US20230299674A1 - Buck Converter and Control Method - Google Patents
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- US20230299674A1 US20230299674A1 US18/056,758 US202218056758A US2023299674A1 US 20230299674 A1 US20230299674 A1 US 20230299674A1 US 202218056758 A US202218056758 A US 202218056758A US 2023299674 A1 US2023299674 A1 US 2023299674A1
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-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
- H02M3/00—Conversion of dc power input into dc power output
- H02M3/02—Conversion of dc power input into dc power output without intermediate conversion into ac
- H02M3/04—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters
- H02M3/10—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
- H02M3/145—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal
- H02M3/155—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only
- H02M3/156—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only with automatic control of output voltage or current, e.g. switching regulators
- H02M3/158—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only with automatic control of output voltage or current, e.g. switching regulators including plural semiconductor devices as final control devices for a single load
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
- H02M1/00—Details of apparatus for conversion
- H02M1/0003—Details of control, feedback or regulation circuits
- H02M1/0009—Devices or circuits for detecting current in a converter
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
- H02M1/00—Details of apparatus for conversion
- H02M1/0003—Details of control, feedback or regulation circuits
- H02M1/0025—Arrangements for modifying reference values, feedback values or error values in the control loop of a converter
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
- H02M1/00—Details of apparatus for conversion
- H02M1/08—Circuits specially adapted for the generation of control voltages for semiconductor devices incorporated in static converters
- H02M1/083—Circuits specially adapted for the generation of control voltages for semiconductor devices incorporated in static converters for the ignition at the zero crossing of the voltage or the current
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
- H02M3/00—Conversion of dc power input into dc power output
- H02M3/02—Conversion of dc power input into dc power output without intermediate conversion into ac
- H02M3/04—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters
- H02M3/06—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using resistors or capacitors, e.g. potential divider
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
- H02M3/00—Conversion of dc power input into dc power output
- H02M3/02—Conversion of dc power input into dc power output without intermediate conversion into ac
- H02M3/04—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters
- H02M3/10—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
- H02M3/145—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal
- H02M3/155—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only
- H02M3/156—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only with automatic control of output voltage or current, e.g. switching regulators
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02M—APPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
- H02M3/00—Conversion of dc power input into dc power output
- H02M3/02—Conversion of dc power input into dc power output without intermediate conversion into ac
- H02M3/04—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters
- H02M3/10—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode
- H02M3/145—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal
- H02M3/155—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only
- H02M3/156—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only with automatic control of output voltage or current, e.g. switching regulators
- H02M3/157—Conversion of dc power input into dc power output without intermediate conversion into ac by static converters using discharge tubes with control electrode or semiconductor devices with control electrode using devices of a triode or transistor type requiring continuous application of a control signal using semiconductor devices only with automatic control of output voltage or current, e.g. switching regulators with digital control
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
- Y02B70/00—Technologies for an efficient end-user side electric power management and consumption
- Y02B70/10—Technologies improving the efficiency by using switched-mode power supplies [SMPS], i.e. efficient power electronics conversion e.g. power factor correction or reduction of losses in power supplies or efficient standby modes
Definitions
- the present invention is directed, in general, to a Direct Current-to-Direct Current (DC/DC) power conversion system and more specifically, to a buck DC/DC converter (also known as a step-down DC/DC converter) that provides the fastest output load transient response and enables end-users to set a desired output voltage using an output feedback resistor divider.
- a buck DC/DC converter also known as a step-down DC/DC converter
- Such a buck DC/DC converter allows end-users to design a power supply for different applications using a single integrated circuit (IC) device.
- the ramp voltage can be generated by an artificial network.
- the ramp voltage is independent of the output ripple voltage.
- the output is connected to the input of the hysteresis comparator through an output feedback divider.
- the output feedback divider is designed so that the output voltage can be regulated at different values.
- One drawback of having this output feedback divider is the attenuation introduced by the output feedback divider reduces the output voltage deviation at the feedback input during an output transient event. The reduced voltage deviation consequently results in slower line and load transient responses.
- FIG. 1 illustrates a schematic diagram of a power converter.
- the power converter 100 is a buck converter comprising an input filter capacitor 101 , a high-side switch 102 , a low-side switch 103 , an output inductor 104 and an output filtering capacitor 105 .
- the hysteresis controller of the power converter 100 comprises a resistor 111 , a capacitor 108 , a hysteresis comparator 112 and a driving circuit block 113 .
- the hysteresis controller of the power converter 100 further comprises an output feedback divider comprising resistors 106 , 107 , 109 and a capacitor 110 .
- the REF voltage shown in FIG. 1 is a constant reference voltage.
- the output voltage (VOUT) of the power converter 100 can be expressed by the following equation:
- V O U T 1 + R106 / R107 ⁇ REF (1)
- R106 is the resistance value of the resistor 106 .
- R107 is the resistance value of the resistor 107 .
- the slow output transient response issue is resolved by adding the capacitor 110 .
- the capacitor 110 functions as a feedforward capacitor to pass the output voltage deviation directly to the inverting input of the hysteresis comparator 112 without any attenuation.
- the capacitor 110 also withstands the DC voltage difference between the output VOUT and the feedback node FB.
- the resistor 109 provides a DC path for the leakage current flowing out of the inverting input of the comparator 112 .
- the resistor 109 and the capacitors 108 and 110 form a high pass filter. This high pass filter is designed such that the majority of the output voltage deviation during an output transient event reaches the inverting input of the hysteresis comparator 112 .
- the hysteresis control method shown in FIG. 1 has three drawbacks.
- the capacitance of the capacitor 110 must be larger than that of the capacitor 108 to avoid a capacitor divider effect when the output voltage deviation is fed into the comparator 112 during an output load transient event. Larger capacitance means more silicon area, extra power consumption and complexity.
- both VOUT and FB inputs are required in the hysteresis control method shown in FIG. 1 .
- This control system configuration is not compatible with the most popular control scheme (e.g., voltage mode control, current mode control and constant-on time control) in which the FB input is the only required input.
- the voltage drop across the inductor DC resistance (DCR) of the output inductor due to the output load current presents at the capacitor 108 .
- DCR DC resistance
- the average voltage of the capacitor 108 varies depending on different output load currents.
- the variation of the voltage across the capacitor 108 has an impact on the voltage at the inverting input of the hysteresis comparator 112 .
- Such a voltage variation at the inverting input of the hysteresis comparator 112 can affect the output transient response of the power converter 100 .
- control apparatus that has only the FB input to set the output voltage at different values for different applications such as Pulse Width Modulation (PWM) applications, Pulse Frequency Modulation (PFM) applications and the like. Meanwhile, the control apparatus is able to achieve the same or similar output transient responses as discussed above with respect to FIG. 1 .
- PWM Pulse Width Modulation
- PFM Pulse Frequency Modulation
- an apparatus comprises a PWM ramp generator coupled between a switching node of a power converter and a first input of a comparator, the PWM ramp generator comprising a first resistor and a first capacitor connected in series between the switching node and the first input of the comparator, and a second resistor and a second capacitor connected in parallel between the first input of the comparator and a feedback node, and a PFM control circuit comprising an error amplifier and a current zero crossing detection comparator, wherein the error amplifier is coupled between a second input of the comparator and a reference node, and the PFM control circuit is configured to generate gate drive signal for the power converter when the power converter is configured to operate in a PFM mode.
- a method comprises in a PWM mode of a power converter, configuring a plurality of control switches such that gate drive signals of the power converter are generated based on a comparison between an output of a PWM ramp generator and a predetermined reference, and in a PFM mode of the power converter, configuring the plurality of control switches such that gate drive signals of the power converter are generated based on signals generated by an error amplifier and a current zero crossing detection comparator.
- a system comprises a high-side switch and a low-side switch connected in series between an input voltage bus and ground, wherein a common node of the high-side switch and the low-side switch is a switching node, an inductor connected between the common node of the high-side switch and the low-side switch and an output of the system, a PWM ramp generator coupled between the switching node and a first input of a comparator, the PWM ramp generator comprising a first resistor and a first capacitor connected in series between the switching node and the first input of the comparator, and a second resistor and a second capacitor connected in parallel between the first input of the comparator and a feedback node, and a PFM control circuit comprising an error amplifier and a current zero crossing detection comparator, wherein the error amplifier is coupled between a second input of the comparator and a reference node, and the PFM control circuit is configured to generate gate drive signal for the system when the system is configured to operate in a PFM mode.
- FIG. 1 illustrates a schematic diagram of a power converter
- FIG. 2 illustrates a power converter and the associated PWM and PFM control circuits in accordance with various embodiments of the present disclosure
- FIG. 3 illustrates a schematic diagram of the power converter shown in FIG. 2 when the power converter is configured to operate in a PWM mode in accordance with various embodiments of the present disclosure
- FIG. 4 illustrates various signals associated with the power converter shown in FIG. 3 in accordance with various embodiments of the present disclosure
- FIG. 5 illustrates a gain versus frequency response curve of the feedback divider network in accordance with various embodiments of the present disclosure
- FIG. 6 illustrates a gain versus frequency response curve of an error amplifier having a dominant pole in accordance with various embodiments of the present disclosure
- FIG. 7 illustrates various signals associated with the error amplifier shown in FIG. 6 in accordance with various embodiments of the present disclosure
- FIG. 8 illustrates a first implementation of the PFM control circuit in accordance with various embodiments of the present disclosure
- FIG. 9 illustrates various voltage and current signals associated with the first implementation of the PFM control circuit shown in FIG. 8 in accordance with various embodiments of the present disclosure
- FIG. 10 illustrates a second implementation of the PFM control circuit in accordance with various embodiments of the present disclosure
- FIG. 11 illustrates various voltage and current signals associated with the second implementation of the PFM control circuit shown in FIG. 10 in accordance with various embodiments of the present disclosure
- FIG. 12 illustrates a third implementation of the PFM control circuit in accordance with various embodiments of the present disclosure
- FIG. 13 illustrates various voltage and current signals associated with the third implementation of the PFM control circuit shown in FIG. 12 in accordance with various embodiments of the present disclosure.
- FIG. 14 illustrates a flow chart of a control method for operating the power converter shown in FIG. 2 in accordance with various embodiments of the present disclosure.
- FIG. 2 illustrates a power converter and the associated PWM and PFM control circuits in accordance with various embodiments of the present disclosure.
- the power converter is a buck converter comprising an input filter capacitor 201 , a high-side switch 202 , a low-side switch 203 , an output inductor 204 and an output filtering capacitor 205 .
- the high-side switch 202 and the low-side switch 203 are connected in series between an input voltage bus and ground.
- a common node of the high-side switch 202 and the low-side switch 203 is the switching node (SW as shown in FIG. 2 ) of the power converter.
- the output inductor 204 is connected between the common node of the high-side switch 202 and the low-side switch 203 , and an output of the power converter.
- the control circuit of the power converter shown in FIG. 2 comprises a PWM ramp generator 210 , a PFM control circuit 250 , a comparator 215 , a feedback divider, and control logic and gate drive circuits 216 .
- the comparator 215 is implemented as a hysteresis comparator.
- the comparator 215 is configured to generate a control signal fed into the control logic and gate drive circuits 216 .
- the feedback divider is formed by resistors 206 and 207 .
- a common node of the resistors 206 and 207 is the feedback node of the power converter.
- a capacitor 208 is connected in parallel with the resistor 206 .
- the capacitor 208 functions as a feedforward capacitor.
- the PWM ramp generator 210 is coupled between the switching node SW of the power converter and a first input of the comparator 215 . More particularly, the PWM ramp generator 210 is connected to the switching node SW through a third control switch S3.
- the PWM ramp generator 210 comprises a first resistor 211 and a first capacitor 212 connected in series between the third control switch S3 and the first input of the comparator 215 .
- the first input is an inverting input of the comparator 215 .
- the PWM ramp generator 210 further comprises a second resistor 214 and a second capacitor 213 connected in parallel between the first input of the comparator 215 and the feedback node FB.
- the PFM control circuit 250 comprises an error amplifier 230 and a current zero crossing detection comparator 220 .
- the error amplifier 230 is coupled between a second input of the comparator 215 and a reference node REF.
- the second input is a non-inverting input of the comparator 215 .
- the PFM control circuit 250 is configured to generate gate drive signal for the power converter when the power converter is configured to operate in a PFM mode.
- the block diagram of the PFM control circuit 250 shown in FIG. 2 merely includes basic function units of the PFM control circuit 250 .
- the structure of the PFM control circuit 250 may vary accordingly.
- a threshold voltage generator may be coupled between the non-inverting input of the comparator 215 and the error amplifier 230 .
- a peak current detection comparator may be employed to determine the on-time of the high-side switch 202 .
- a constant on-time generator may be employed to determine the on-time of the high-side switch.
- FIGS. 12 - 13 The detailed implementation of this PFM control scheme will be described below with respect to FIGS. 12 - 13 .
- a first control switch S1 is connected between the first input of the comparator 215 and the feedback node FB.
- a second control switch S2 is connected between the second input of the comparator 215 and the reference node REF.
- the third control switch S3 is connected between the switching node SW and the first resistor 211 .
- the second switch S2 and the third switch S3 are configured to be turned on, and the first switch S1 is configured to be turned off when the power converter is configured to operate in a PWM mode.
- the second switch S2 and the third switch S3 are configured to be turned off, and the first switch S1 is configured to be turned on when the power converter is configured to operate in the PFM mode.
- the third switch S3 can be placed any location between the switching node SW and the first input of the comparator 215 . In other words, the third switch S3 is coupled between the switching node SW and the first input of the comparator 215 . It should further be noted that depending on design needs, the locations of the first resistor 211 and the first capacitor 212 can be swapped.
- a resistor-capacitor filter (not shown) may be connected to the switching node SW.
- the resistor-capacitor filter is configured such that an output voltage of the resistor-capacitor filter is used to determine an output voltage of the power converter when the power converter is configured to operate in the PFM mode during an initial power up period.
- Vo can be used, together with the input voltage, to determine the output value of the constant-on-time generator used in the constant-on time PFM control.
- the PWM ramp generator 210 may be integrated into a single IC device or on a printed circuit board.
- the power switches 202 and 203 may be integrated into this single IC device too.
- the PWM ramp generator 210 In the PWM mode operation, the PWM ramp generator 210 generates a saw-tooth like ramp voltage on top of the voltage on the FB node. The sum of the saw-tooth like ramp voltage and the voltage on the FB node is compared with the REF voltage to control the on and off time intervals of the power switches 202 and 203 , thereby regulating the output voltage of the power converter within the specification limits.
- the capacitor 208 is introduced to pass the output voltage deviation from VOUT to the feedback node FB, and then to the inverting input of the hysteresis comparator 215 with very little attenuation, resulting good output transient responses as well as good DC regulation.
- the capacitance value of the capacitor 208 is chosen such that the impedance formed by the resistor 206 and the capacitor 208 is much smaller than the impedance formed by the capacitor 213 and resistor 214 at the interested switching frequencies.
- the impedance formed by resistor 214 and capacitor 213 is at least five times greater than the impedance formed by the resistor 206 and the capacitor 208 .
- the DC voltage difference between VOUT and the feedback node FB drops across resistors 211 , 214 and capacitors 212 , 213 . Since the capacitor 213 and the resistor 214 are connected in parallel, the DC impedance of these two is determined by the resistor 214 . The resistor 211 and the capacitor 212 are connected in series. The DC impedance of these two is determined by the capacitor 212 .
- resistors 211 and 214 are designed in such a way that the value of resistor 211 is much larger (e.g., 211 is 10 ⁇ larger than 214 ) than that of the resistor 214 , the majority of the DC voltage difference between the VOUT node and the feedback node FB drops across the capacitor 212 .
- This relationship has nothing to do with the capacitance of the capacitor 212 .
- this relationship is still valid when the capacitance of the capacitor 212 can be even smaller than that of the capacitor 213 .
- One advantageous feature of having the power converter shown in FIG. 2 is that all control components can be integrated into a single IC device. Furthermore, most of the voltage across the DCR of the output inductor due to the output current also drops across the capacitor 212 at steady state. During an output load transient event, when the output current varies, the voltage across the DCR of the output inductor varies too. The voltage across the capacitor 212 cannot change instantaneously. Therefore, the varying voltage drops across the resistors 211 and 214 . Since the resistance value of the resistor 214 is much smaller than that of the resistor 211 , the majority of the varying voltage drops across the resistor 211 .
- the voltage level at the inverting input of the hysteresis comparator 215 maintains relatively constant.
- the capacitor 212 is not in the path between the output node VOUT and the inverting input of the hysteresis comparator 215 during an output load transient event. Thus, the capacitor 212 does not cause a capacitor divider effect.
- FIG. 3 illustrates a schematic diagram of the power converter shown in FIG. 2 when the power converter is configured to operate in a PWM mode in accordance with various embodiments of the present disclosure.
- the PWM ramp generator 210 comprises a first resistor 211 and a first capacitor 212 connected in series between the switching node SW and the inverting input of the comparator 215 .
- the PWM ramp generator 210 further comprises a second resistor 214 and a second capacitor 213 connected in parallel between the inverting input of the comparator 215 and the feedback node FB.
- the resistor 214 provides a path for the leakage current flowing out of the inverting input of the comparator 215 .
- the resistor 214 can eliminate the effect of the voltage divider formed by capacitors 212 and 213 . As a result, the majority of the DC voltage difference between VOUT and the feedback node FB drops across the capacitor 212 regardless of the capacitance value of the capacitor 212 .
- the resistors 211 , 214 , and the capacitors 212 and 213 are employed to generate a saw tooth like ramp voltage V RAMP applied to the inverting input of the comparator 215 .
- the voltage on the switching node SW is pulled up to the input voltage VIN after the high-side switch 202 is turned on.
- the voltage on the switching node SW is pulled down to ground after the high-side switch 202 is turned off and the low-side switch 203 is turned on.
- the capacitor 213 is charged by the voltage on SW through the resistor 211 and the capacitor 212 .
- the capacitor 213 is discharged through the resistor 211 and the capacitor 212 .
- a ramp voltage V RAMP is generated across the capacitor 213 .
- the voltage across the capacitor 213 is connected to the feedback node FB.
- the capacitance of the capacitor 208 is much larger than that of the capacitor 213 . Since the capacitor value of the capacitor 208 is much larger than that of capacitor 213 , any voltage deviation at VOUT is passed to the feedback node FB through the capacitor 208 with little attenuation. This feature helps the power converter 200 archive a fast transient response during an output transient event.
- the amplitude of the ramp voltage V RAMP across the capacitor 213 can be adjusted by adjusting a time constant.
- the time constant ⁇ is given by the following equation:
- Equation (2) R211 is the resistance of the resistor 211 .
- R214 is the resistance of the resistor 214 .
- C213 is the capacitance of the capacitor 213 .
- the time constant ⁇ should be much larger than the interested PWM switching period. For example, the time constant ⁇ is at least five times greater than the interested PWM switching period.
- the time constant determined by Equation (2) determines the gain of the hysteresis comparator.
- the gain has an impact on the stability of the close loop performance of the power converter 200 .
- the voltage REF at the non-inverting input of the comparator 215 includes a square waveform (not shown but illustrated in FIG. 4 ).
- the peak and valley values of the square waveform represent the trigger thresholds of the comparator 215 to turn on and turn off the high-side switch 202 , respectively.
- the difference between the peak and valley values of the square waveform represents the hysteresis of the comparator 215 . This difference determines the switching frequency of the power converter 200 .
- the threshold i.e. the difference between the peak and valley values
- phase lock loop (PLL) circuit can be employed to adjust the difference between the peak and valley values of the REF voltage to keep the switching frequency constant over a wide input and/or output voltage range.
- FIG. 4 illustrates various signals associated with the power converter shown in FIG. 3 in accordance with various embodiments of the present disclosure.
- the horizontal axis represents intervals of time.
- the first row represents the output voltage of the power converter shown in FIG. 3 .
- the second row represents the ramp voltage V RAMP and the reference voltage REF.
- the solid line of the second row represents the ramp voltage V RAMP .
- the dotted line represents the square waveform portion of the reference voltage REF.
- the third row represents the current I L flowing through the inductor of the power converter.
- the fourth row represents the output voltage (Vc) of the comparator 215 .
- the fifth row represents the gate drive signal V GS1 of the high-side switch of the power converter.
- the sixth row represents the gate drive signal V GS2 of the low-side switch of the power converter.
- the high-side switch 202 is turned on.
- the reference voltage REF jumps from a valley value to a peak value. From t1 to t2, the high-side switch 202 is on.
- the capacitor 213 is charged by the input voltage VIN, which is applied to the switching node SW once the high-side switch 202 is on.
- the comparator 215 since the voltage at the inverting input of the comparator 215 reaches the peak value of the reference voltage REF, the comparator 215 triggers.
- the output of the comparator 215 generates signals to turn off the high-side switch 202 , and turn on the low-side switch 203 through the control logic and gate drive circuits 216 .
- the reference voltage REF switches back to its valley value to keep the output status of the comparator 215 .
- the switching node SW is pulled down to ground by the low-side switch 203 .
- the capacitor 213 is discharged and the voltage at the inverting input of the comparator 215 decreases.
- the voltage at inverting input reaches the valley value of the reference voltage REF.
- the comparator 215 triggers.
- the output of the comparator 215 generates signals to turn off the low-side switch 203 , and turn on the high-side switch 202 through the control logic and gate drive circuits 216 .
- the switching cycles repeats as shown in FIG. 4 .
- various voltage deviations may occur at the output of the power converter 200 .
- the voltage deviations are caused by either a line transient or an output load transient. Depending on different operating conditions, the voltage deviation may be either an overshoot or an undershoot. Furthermore, the voltage deviation may occur in any time durations shown in FIG. 4 (e.g., from t1 to t2 or from t2 to t3).
- the control circuit shown in FIG. 3 is able to provide a fast transient response to maintain the output voltage within specification limits. The discussion below explains how the control circuit shown in FIG. 3 is able to provide a fast transient response under different voltage deviations.
- the voltage deviation In operation, if the voltage deviation is in an undershoot condition, and the high-side switch 202 is on (from t1 to t2), the voltage deviation causes the voltage at the inverting input of the comparator 215 to decrease. As shown in FIG. 4 , the decreased voltage at the inverting input of the comparator 215 increases the conduction time of the high-side switch 202 . The increased conduction time of the high-side switch 202 helps to increase the output voltage, thereby reducing the voltage deviation. On the other hand, if the voltage deviation is in an undershoot condition, and the low-side switch 203 is on (from t2 to t3), the voltage deviation causes a voltage dip at the inverting input of the comparator 215 .
- the voltage dip at the inverting input of the comparator 215 shortens the conduction time of the low-side switch 203 .
- the reduced conduction time of the low-side switch 203 helps to increase the output voltage, thereby reducing the voltage deviation.
- the voltage deviation In operation, if the voltage deviation is in an overshoot condition, and the high-side switch 202 is on (from t1 to t2), the voltage deviation causes the voltage at the inverting input of the comparator 215 to increase. According to the operating principle shown FIG. 4 , the increased voltage at the inverting input of the comparator 215 reduces the conduction time of the high-side switch 202 . The reduced conduction time of the high-side switch 202 helps to reduce the output voltage, thereby reducing the voltage deviation. On the other hand, if the voltage deviation is in an overshoot condition, and the low-side switch 203 is on (from t2 to t3), the voltage deviation causes a voltage overshoot at the inverting input of the comparator 215 .
- the voltage overshoot at the inverting input of the comparator 215 increases the conduction time interval of the low-side switch 203 .
- the increased conduction time of the low-side switch 203 helps to reduce the output voltage, thereby reducing the voltage deviation.
- the power converter 200 under the hysteresis control can response to the output voltage deviation instantly regardless of which switch (switch 202 or switch 203 ) is on at the time when the deviation event occurs.
- the power converter 200 shown in FIG. 3 is able to provide the fastest output transient response and the control circuit of the power converter 200 can be integrated in one single IC.
- the power converter may be configured to operate in a very light load condition.
- the power converter In the light load condition, the power converter is configured to operate in the PFM mode to reduce power losses.
- an error amplifier is employed to improve the performance of the control circuit.
- FIGS. 5 - 6 below explain why a dominant pole error amplifier is employed in the PFM mode.
- FIG. 5 illustrates a gain versus frequency response curve of the feedback divider network in accordance with various embodiments of the present disclosure.
- the output feedback divider network 300 is shown in the dashed rectangle 550 .
- the resistors 301 and 302 determines the output voltage.
- the output voltage (VOUT) of the power converter can be expressed by the following equation:
- V O U T 1 + R301 / R302 ⁇ REF (3)
- R301 is the resistance value of the resistor 301 .
- R302 is the resistance value of the resistor 302 .
- the feedback node FB is connected to a first input of an error amplifier.
- REF is connected to a second input of the error amplifier.
- REF is a predetermined reference voltage.
- the capacitor 303 helps the control circuit improve the output transient response.
- the gain of the voltage at FB node over the output voltage VOUT is expressed by the following equation:
- the gain in Equation (4) is plotted in the dashed rectangle 560 .
- the attenuation provided by resistors 301 and 302 diminishes as the frequency increases. Once the frequency reaches a level above 100 kHz, there is very little attenuation.
- the switching frequency is a function of the output load current. Under different load currents, the switching frequency varies in a wide range from a few hertz up to several megahertz.
- the output ripple voltage is fed into the inverting input of the comparator directly.
- Such an implementation is simple and effective. However, this implementation cannot be operated with an output of the feedback divider.
- the gain at a frequency less than 10 kHz is about 0.17.
- a 20-mV ripple voltage at the output VOUT can generate a voltage deviation of about 20 mV at the feedback node FB without any attenuation when the PFM switching frequency is 1 Megahertz.
- a 20-mV ripple voltage at the output VOUT can generate a voltage deviation of about 3.4 mV at the feedback node FB with attenuation when the PFM switching frequency is 10 kHz.
- Such a small output ripple voltage at the feedback node FB fed to the inverting input of the comparator may cause a false trigger, thereby resulting in frequency jittering and irregular output ripple voltages.
- a voltage error amplifier having a dominant pole is introduced to improve the performance of the power converter in the PFM mode.
- FIG. 6 illustrates a gain versus frequency response curve of an error amplifier having a dominant pole in accordance with various embodiments of the present disclosure.
- the error amplifier having a dominant pole is illustrated in the dashed rectangle 650 .
- the error amplifier is implemented as a transconductance operational amplifier 403 .
- a resistor 402 and a capacitor 401 are connected in parallel between the output of the error amplifier 403 and ground.
- the frequency of the dominant pole is determined by the product of the capacitance of the capacitor 401 and the resistance of the resistor 402 .
- the DC gain is determined by the product of Gm (the gain of the transconductance operational amplifier) and the resistance of the resistor 402 .
- the gain of the voltage V ER at the output of the error amplifier over the voltage V FB at the feedback node FB is expressed by the following equation:
- the gain is plotted in the dashed rectangle 660 .
- the gain is very high (about 70 dB) when the frequency is less than 10 Hz, and the gain is below 0 dB when frequency is above 100 kHz.
- the gain shown in FIG. 6 indicates the voltage on the feedback node FB is amplified if the switching frequency is less than 100 kHz.
- the voltage on the feedback node FB is attenuated if the frequency is above 100 kHz.
- the error amplifier 403 shown in FIG. 6 will be used in the PFM operation, which will be discussed below with respect to FIGS. 8 - 13 .
- the dominant pole of the error amplifier 403 should be designed such that a 0 dB frequency is higher than the pole frequency formed by a feedback divider (e.g., the pole formed by resistors 506 , 507 , and feedforward capacitor 508 shown in FIG. 8 ).
- a feedback divider e.g., the pole formed by resistors 506 , 507 , and feedforward capacitor 508 shown in FIG. 8 .
- FIG. 7 illustrates various signals associated with the error amplifier shown in FIG. 6 in accordance with various embodiments of the present disclosure.
- the horizontal axis represents intervals of time.
- the second row represents the voltage V FB on the feedback node FB.
- the third row represents the voltage V ER at the output of the error amplifier.
- the error amplifier is able to improve the noise immunity of the FPM hysteresis comparator if the ripple voltage on the feedback node FB is compared with the output voltage of the voltage error amplifier at a low PFM operating frequency.
- the output voltage of the voltage error amplifier may drop below a predetermined clamping point.
- an active clamp (not shown) can be used to prevent the output of the error amplifier from going too low at a very low frequency. For example, from t1 to t2, the output of the error amplifier is clamped so as to keep the output of the error amplifier over a predetermined clamping point (Clamp shown in FIG. 7 ).
- FIG. 8 illustrates a first implementation of the PFM control circuit in accordance with various embodiments of the present disclosure.
- S2 and S3 shown in FIG. 2 are turned off, and S1 is turned on.
- the circuit shown in FIG. 2 can be simplified as the circuit shown in FIG. 8 .
- a threshold voltage generator 515 is added into the PFM control circuit.
- the threshold voltage generator 515 is coupled between the second input of the comparator 513 and an output of the error amplifier 514 .
- the function units in the dashed rectangle 510 are the PFM control circuit of the power converter 500 .
- the power converter 500 comprises a buck power stage, an output feedback divider, and the PFM control circuit.
- the buck power stage comprises an input filtering capacitor 501 , power switches 502 , 503 , an output inductor 504 and an output filter capacitor 505 .
- the output feedback divider comprises resistors 506 , 507 , and a feedforward capacitor 508 .
- the PFM control circuit comprises control logic and gate drive circuits 511 , a current zero crossing detection comparator 512 , a comparator 513 , a threshold voltage generator 515 and an error amplifier 514 .
- the error amplifier 514 is a transconductance operation amplifier having a dominant pole such as the error amplifier shown in FIG. 6 .
- the capacitor 401 and the resistor 402 are connected in parallel between the output of the error amplifier and ground. The capacitor 401 and the resistor 402 form the dominant pole.
- a non-inverting input of the error amplifier 514 is connected to a predetermined reference REF.
- An inverting input of the error amplifier 514 is connected to the feedback node as shown in FIG. 6 .
- a comparison of a voltage V FB on the feedback node, and a sum of an output voltage V ER of the error amplifier 514 and a threshold voltage V TH from the threshold voltage generator 515 is used to determine an on-time of the high-side switch 502 of the power converter 500 .
- a comparison of the voltage V FB on the feedback node and the output voltage V ER of the error amplifier 514 is used to determine a turn-on instant of the high-side switch 502 of the power converter 500 .
- the current zero crossing detection comparator 512 is configured to determine an on-time of the low-side switch 503 of the power converter 500 once a current flowing through the low-side switch of the power converter reaches zero.
- FIG. 9 illustrates various voltage and current signals associated with the first implementation of the PFM control circuit shown in FIG. 8 in accordance with various embodiments of the present disclosure.
- the horizontal axis represents intervals of time.
- the first row represents the output voltage of the power converter shown in FIG. 8 .
- the second row represents the current I_Q1 flowing through the high-side switch of the power converter.
- the third row represents the current I_Q2 flowing through the low-side switch of the power converter.
- the fourth row represents the current I L flowing through the inductor of the power converter.
- the fifth row represents the signal V1 shown in FIG. 8 .
- the sixth row represents the signal V2 shown in FIG. 8 .
- the seventh row represents the signal V3 shown in FIG. 8 .
- the eighth row represents the output voltage V ER of the error amplifier and the voltage V FB on the feedback node.
- the solid line is V ER
- the dashed line is V FB .
- the ninth row represents the gate drive signal V GS1 of the high-side switch of the power converter.
- the tenth row represents the gate drive signal V GS2 of the low-side switch of the power converter.
- the inductor current I L is charged from zero, and the output ripple voltage increases.
- the voltage on the feedback node FB increases too. Since the voltage on the feedback node FB is fed into the inverting input of the error amplifier (shown in FIG. 6 ), the output voltage V ER of the voltage error amplifier decreases.
- the output of the comparator 513 triggers (from a logic high state to a logic low state).
- the logic signal V1 flips from a logic high state to a logic low state at t2.
- the logic signal V3 flips from a logic low state to a logic high state at t2.
- the control logic and gate drive circuits 511 turn off the high-side switch 502 and turn on the low-side switch 503 at t2 as shown in FIG. 9 .
- the current zero crossing detection comparator 512 is enabled to monitor the current (I_Q503) flowing through the low-side switch 503 , and the logic signal V2 changes from a logic low state to a logic high state at t2.
- the logic signal V2 changes from a logic high state to a logic low state at t3.
- This logic state change of V2 causes the control logic and gate drive circuits 511 to turn off the low-side switch 503 at t3, and keep the high-side switch 502 off as shown in FIG. 9 .
- the threshold voltage from the threshold voltage generator 515 is removed.
- the output of the voltage error amplifier is connected to the comparator directly.
- both switches 502 and 503 are off.
- the output voltage of the power converter decreases since the output load current is maintained by discharging the output capacitor 505 .
- the voltage (V FB ) at the inverting input of the comparator 513 reaches the output voltage of the voltage error amplifier.
- the control logic signal V3 flips from a logic high state to a logic low state.
- the control logic signal V1 flips from a logic low state to a logic high state.
- the comparator 513 triggers again, and the operation cycle repeats as shown in FIG. 9 .
- the threshold voltage V TH can be adjusted to control the energy delivered to the output over each PFM switching cycle.
- the amount of energy delivered to the output over one PFM cycle also determines the peak-to-peak output ripple voltage in the PFM mode operation.
- the output voltage deviation is in an undershoot condition, and the output voltage deviation occurs at the time interval (e.g., from t3 to t4) when both switches 502 and 503 are off, the output voltage deviation causes a voltage undershoot at the feedback node FB.
- the voltage undershoot at the feedback node FB pulls the voltage at its inverting input of the comparator 513 low to cross the voltage at the non-inverting input of the comparator 513 .
- the comparator 513 triggers to turn on the high-side switch 502 to deliver the energy from the input to the output to hold the output voltage in regulation.
- the output undershoot event occurs at the time interval (e.g., from t1 to t2) when the high-side switch 502 is on.
- the voltage dip at the inverting input of the comparator 513 increases the time to reach the voltage at non-inverting input of the comparator 513 .
- the high-side switch 502 remains on for a longer time to deliver more energy from the input to the output to keep the output voltage in regulation.
- the output voltage deviation is in an overshoot condition, and the output voltage deviation occurs at the time interval (e.g., from t3 to t4) when both switches 502 and 503 are off, the output voltage overshoot causes the voltage at the inverting input of the comparator 513 to increase.
- the increased voltage at the inverting input of the comparator 513 causes a delayed trigger.
- both switches 502 and 503 remain off for a longer time to reduce the amount of energy delivered to the output over one PFM switching cycle, thereby maintaining the output voltage in regulation.
- the output overshoot event occurs at the time interval (e.g., from t1 to t2) when the high-side switch 502 is on.
- the overshoot causes the voltage at the inverting input of the comparator 513 to increase.
- the increased voltage at the inverting input of the comparator 513 causes an early trigger of the comparator 513 .
- the early trigger turns off the high-side switch 502 to reduce the energy delivered to the output over one PFM switching cycle, thereby maintaining the output voltage in regulation.
- the voltage threshold V TH determines the amount of energy deliver to the output of the power converter over one PFM switching cycle.
- the voltage threshold V TH also determines the peak-to-peak output ripple voltage during the PFM operation.
- the threshold voltage V TH can be adjusted based on the input voltage and the output voltage to keep the output ripple voltage in the PFM mode relatively constant.
- FIG. 10 illustrates a second implementation of the PFM control circuit in accordance with various embodiments of the present disclosure.
- S2 and S3 shown in FIG. 2 are turned off, and S1 is turned on.
- the circuit shown in FIG. 2 can be simplified as the circuit shown in FIG. 10 .
- a peak current detection comparator 615 is added into the PFM control circuit.
- the peak current detection comparator 615 is configured to receive the current (I_Q602) flowing through the high-side switch 602 and a predetermined peak current reference I PK_REF .
- the function units in the dashed rectangle 610 are the PFM control circuit of the power converter 600 .
- the power converter 600 comprises a buck power stage, an output feedback divider, and the PFM control circuit.
- the buck power stage comprises an input filtering capacitor 601 , power switches 602 , 603 , an output inductor 604 and an output filter capacitor 605 .
- the output feedback divider comprises resistors 606 , 607 and a feedforward capacitor 608 .
- the PFM control circuit comprises control logic and gate drive circuits 611 , a current zero crossing detection comparator 612 , a comparator 613 , a peak current detection comparator 615 and an error amplifier 614 .
- the error amplifier 614 is a transconductance operation amplifier having a dominant pole such as the error amplifier shown in FIG. 6 .
- the capacitor 401 and the resistor 402 are connected in parallel between the output of the error amplifier and ground. The capacitor 401 and the resistor 402 form the dominant pole.
- a comparison of a current of the high-side switch 602 (I_Q602) and the peak current reference I PK_REF at the peak current detection comparator 615 is used to determine an on-time of the high-side switch 602 of the power converter 600 .
- a comparison of the voltage on the feedback node and the output voltage of the error amplifier is used to determine a turn-on instant of the high-side switch 602 of the power converter 600 .
- the current zero crossing detection comparator 612 is configured to determine an on-time of the low-side switch 603 of the power converter 600 once a current flowing through the low-side switch of the power converter reaches zero.
- FIG. 11 illustrates various voltage and current signals associated with the second implementation of the PFM control circuit shown in FIG. 10 in accordance with various embodiments of the present disclosure.
- the horizontal axis represents intervals of time.
- the second row represents the current I_Q1 flowing through the high-side switch of the power converter.
- the third row represents the current I_Q2 flowing through the low-side switch of the power converter.
- the fourth row represents the current I L flowing through the inductor of the power converter.
- the fifth row represents the signal V1 shown in FIG. 10 .
- the sixth row represents the signal V2 shown in FIG. 10 .
- the seventh row represents the signal V3 shown in FIG. 10 .
- the eighth row represents the output voltage V ER of the error amplifier and the voltage V FB on the feedback node.
- the solid line is V ER
- the dashed line is V FB .
- the ninth row represents the gate drive signal V GS1 of the high-side switch of the power converter.
- the tenth row represents the gate drive signal V GS2 of the low-side switch of the power converter.
- the inductor current I L is charged from zero, and the output ripple voltage increases.
- the voltage on the feedback node FB increases too. Since the voltage on the feedback node FB is fed into the inverting input of the error amplifier (shown in FIG. 6 ), the output voltage of the voltage error amplifier decreases.
- the peak current detection comparator 615 triggers at t2 and generates a short low pulse at the control logic signal V1 (from a logic high state to a logic low state at t2). In response to this short low pulse, the control logic and gate drive circuits 611 turn off the high-side switch 602 and turn on the low-side switch 603 at t2 as shown in FIG. 11 .
- the current zero crossing detection comparator 612 is enabled to monitor the current (I_Q603) flowing through the low-side switch 603 , and the logic signal V2 changes from a logic low state to a logic high state at t2. Once the current flowing through the low-side switch 603 reaches zero, the logic signal V2 changes from a logic high state to a logic low state at t3. This logic state change of V2 causes the control logic and gate drive circuits 611 to turn off the low-side switch 603 at t3, and keep the high-side switch 602 off as shown in FIG. 11 .
- the voltage (V FB ) at the inverting input of the comparator 613 reaches the output voltage of the voltage error amplifier.
- the comparator 613 triggers accordingly.
- the comparator 613 generates a short low pulse at the control logic signal V3.
- the control logic signal V3 flips from a logic high state to a logic low state at t4.
- the logic state change of V3 causes the control logic and gate drive circuits 611 to turn on the high-side switch 602 , and keep the low-side switch 603 off.
- the inductor current starts to charge up from zero.
- the peak current detection comparator 615 triggers and generates a short pulse on the control logic signal V1, causing the control logic and gate drive circuits 611 to turn off the power switch 602 and turn on the power switch 603 .
- the control logic signal V2 resets from a logic low state to a logic high state, and the zero current crossing detection comparator 612 is enabled.
- the PFM mode switching cycle repeats as shown in FIG. 11 .
- the amount of energy delivered to the output can be controlled by controlling the peak inductor current.
- the transient response of the power converter 600 is very similar to that of the power converter 500 , and hence is not repeated herein.
- FIG. 12 illustrates a third implementation of the PFM control circuit in accordance with various embodiments of the present disclosure.
- S2 and S3 shown in FIG. 2 are turned off, and S1 is turned on.
- the circuit shown in FIG. 2 can be simplified as the circuit shown in FIG. 12 .
- a constant on-time generator 715 is added into the PFM control circuit.
- the constant on-time generator 715 is configured to receive the input voltage VIN and the sensed output voltage VOUT_S.
- the function units in the dashed rectangle 710 are the PFM control circuit of the power converter 700 .
- a resistor-capacitor low pass filter is needed to obtain the sensed the output voltage from the SW node since the PFM control circuit does not have any access to the actual output voltage.
- the output voltage is determined once the output feedback divider is determined and the reference voltage of the voltage error amplifier, REF, is known. Therefore, the output voltage sense can be done each time during the soft start period to detect the output voltage through the SW switching node. There is no need to continue sense the output voltage during the operation.
- the power converter 700 comprises a buck power stage, an output feedback divider, and the PFM control circuit.
- the buck power stage comprises an input filtering capacitor 701 , power switches 702 , 703 , an output inductor 704 and an output filter capacitor 705 .
- the output feedback divider comprises resistors 706 , 707 , and a feedforward capacitor 708 .
- the PFM control circuit comprises control logic and gate drive circuits 711 , a current zero crossing detection comparator 712 , a comparator 713 , a constant on-time generator 715 and an error amplifier 714 .
- the error amplifier 714 is a transconductance operation amplifier having a dominant pole such as the error amplifier shown in FIG. 6 .
- the capacitor 401 and the resistor 402 are connected in parallel between the output of the error amplifier and ground. The capacitor 401 and the resistor 402 form the dominant pole.
- an output of the constant on-time generator 715 is used to determine an on-time of the high-side switch 702 of the power converter 700 .
- a comparison of the voltage on the feedback node and the output voltage of the error amplifier is used to determine a turn-on instant of the high-side switch 702 of the power converter 700 .
- the current zero crossing detection comparator 712 is configured to determine an on-time of the low-side switch 703 of the power converter 700 once a current flowing through the low-side switch of the power converter reaches zero.
- FIG. 13 illustrates various voltage and current signals associated with the third implementation of the PFM control circuit shown in FIG. 12 in accordance with various embodiments of the present disclosure.
- the horizontal axis represents intervals of time.
- the second row represents the current I_Q1 flowing through the high-side switch of the power converter.
- the third row represents the current I_Q2 flowing through the low-side switch of the power converter.
- the fourth row represents the current I L flowing through the inductor of the power converter.
- the fifth row represents the signal V1 shown in FIG. 12 .
- the sixth row represents the signal V2 shown in FIG. 12 .
- the seventh row represents the signal V3 shown in FIG. 12 .
- the eighth row represents the output voltage V ER of the error amplifier and the voltage V FB on the feedback node.
- the solid line is V ER
- the dashed line is V FB .
- the ninth row represents the gate drive signal V GS1 of the high-side switch of the power converter.
- the tenth row represents the gate drive signal V GS2 of the low-side switch of the power converter.
- the inductor current I L is charged from zero, and the output ripple voltage increases.
- the voltage on the feedback node FB increases too. Since the voltage on the feedback node FB is fed into the inverting input of the error amplifier (shown in FIG. 6 ), the output voltage of the voltage error amplifier decreases.
- the constant on-time generator 715 pulls the control logic signal V1 low (from a logic high state to a logic low state at t2). In response to this short low pulse, the control logic and gate drive circuits 711 turn off the high-side switch 702 and turn on the low-side switch 703 at t2 as shown in FIG. 13 .
- the current zero crossing detection comparator 712 is enabled to monitor the current (I_Q703) flowing through the low-side switch 703 , and the logic signal V2 changes from a logic low state to a logic high state at t2. Once the current flowing through the low-side switch 703 reaches zero, the logic signal V2 changes from a logic high state to a logic low state at t3. This logic state change of V2 causes the control logic and gate drive circuits 711 to turn off the low-side switch 703 at t3, and keep the high-side switch 702 off as shown in FIG. 13 .
- the voltage (V FB ) at the inverting input of the comparator 713 reaches the output voltage of the voltage error amplifier.
- the comparator 713 triggers accordingly.
- the comparator 713 generates a short low pulse at the control logic signal V3.
- the short low pulse at the control logic signal V3 enables the constant on-time generator 715 .
- the control logic signal V1 changes from low to high.
- the logic state change of V1 causes the control logic and gate drive circuits 711 to turn on the high-side switch 702 , and keep the low-side switch 703 off.
- the inductor current starts to charge up from zero.
- control logic signal V1 is pulled low and causes the control logic and gate drive circuits 711 to turn off the power switch 702 and turn on the power switch 703 .
- the control logic signal V2 resets from a logic low state to a logic high state, and the zero current crossing detection comparator 712 is enabled.
- the PFM mode switching cycle repeats as shown in FIG. 13 .
- the amount of energy delivered to the output can be controlled by adjusting the constant on-time interval.
- the transient response of the power converter 700 is very similar to that of the power converter 500 , and hence is not repeated herein.
- FIG. 14 illustrates a flow chart of a control method for operating the power converter shown in FIG. 2 in accordance with various embodiments of the present disclosure.
- This flowchart shown in FIG. 14 is merely an example, which should not unduly limit the scope of the claims.
- One of ordinary skill in the art would recognize many variations, alternatives, and modifications. For example, various steps illustrated in FIG. 14 may be added, removed, replaced, rearranged and repeated.
- a plurality of control switches is configured such that gate drive signals of the power converter are generated based on a comparison between an output of a PWM ramp generator and a predetermined reference.
- the plurality of control switches is configured such that gate drive signals of the power converter are generated based on signals generated by an error amplifier and a current zero crossing detection comparator.
- a high-side switch and a low-side switch are connected in series between an input voltage bus and ground, wherein a common node of the high-side switch and the low-side switch is a switching node of the power converter.
- an inductor is connected between the common node of the high-side switch and the low-side switch and an output of the power converter.
- a PWM ramp generator is coupled between the switching node of the power converter and a first input of a comparator, and wherein the PWM ramp generator comprises a first resistor and a first capacitor connected in series between the switching node and the first input of the comparator, and a second resistor and a second capacitor connected in parallel between the first input of the comparator and a feedback node.
- the comparator has an output coupled to control logic and gate drive circuits.
- the error amplifier is coupled between a second input of the comparator and a reference node.
- a current zero crossing detection comparator is coupled to the control logic and gate drive circuits.
- a first control switch of the plurality of control switches is connected between the first input of the comparator and the feedback node.
- a second control switch of the plurality of control switches is connected between the second input of the comparator and the reference node.
- a third control switch of the plurality of control switches is coupled between the switching node and the first input of the comparator.
- the method further comprises in the PWM mode of the power converter, configuring the second switch and the third switch to be turned on, and configuring the first switch to be turned off.
- the method further comprises in the PFM mode of the power converter, configuring the second switch and the third switch to be turned off, and configuring the first switch to be turned on.
- the method further comprises in the PFM mode of the power converter, comparing a voltage on the feedback node with a sum of an output voltage of the error amplifier and a threshold voltage from a threshold generator to determine an on-time of the high-side switch of the power converter, comparing the voltage on the feedback node and the output voltage of the error amplifier to determine a turn-on instant of the high-side switch of the power converter, and determining, by the current zero crossing detection comparator, an on-time of the low-side switch of the power converter once a current flowing through the low-side switch of the power converter reaches zero.
- the method further comprises in the PFM mode of the power converter, comparing a current flowing through the high-side switch of the power converter with a predetermined peak current reference to determine an on-time of the high-side switch of the power converter, comparing a voltage on the feedback node with an output voltage of the error amplifier to determine a turn-on instant of the high-side switch of the power converter, and determining, by the current zero crossing detection comparator, an on-time of the low-side switch of the power converter once a current flowing through the low-side switch of the power converter reaches zero.
- the method further comprises in the PFM mode of the power converter, determining an on-time of the high-side switch of the power converter based on an output of a constant on-time generator, comparing a voltage on the feedback node with an output voltage of the error amplifier to determine a turn-on instant of the high-side switch of the power converter, and determining, by the current zero crossing detection comparator, an on-time of the low-side switch of the power converter once a current flowing through the low-side switch of the power converter reaches zero.
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Abstract
An apparatus includes a PWM ramp generator coupled between a switching node of a power converter and a first input of a comparator, the PWM ramp generator comprising a first resistor and a first capacitor connected in series between the switching node and the first input of the comparator, and a second resistor and a second capacitor connected in parallel between the first input of the comparator and a feedback node, and a PFM control circuit comprising an error amplifier and a current zero crossing detection comparator, wherein the error amplifier is coupled between a second input of the comparator and a reference node, and the PFM control circuit is configured to generate gate drive signal for the power converter when the power converter is configured to operate in a PFM mode.
Description
- This application claims the benefit of U.S. Provisional Application No. 63/268,112, filed on Feb. 16, 2022, entitled “Buck Converter and Control Method,” which application is hereby incorporated herein by reference.
- The present invention is directed, in general, to a Direct Current-to-Direct Current (DC/DC) power conversion system and more specifically, to a buck DC/DC converter (also known as a step-down DC/DC converter) that provides the fastest output load transient response and enables end-users to set a desired output voltage using an output feedback resistor divider. Such a buck DC/DC converter allows end-users to design a power supply for different applications using a single integrated circuit (IC) device.
- Modern developments in mobile devices (e.g., smartphones), tablets, notebooks, and data centers require DC/DC converters having the fastest line and load transient responses. On the other hand, each DC/DC converter is designed to be suitable for many different system applications so as to simplify logistic processes.
- A variety of control schemes have been applied to buck converters. Among all control schemes applied to the buck converters, the hysteresis control scheme has been widely adopted because of its fastest output transient responses under either a line or an output load transient event. However, to achieve the fastest output transient responses, the output voltage must be fed back to the hysteresis comparator directly, resulting in a limited output voltage range in which the hysteresis control buck converter is able to operate. This is because in many cases the output ripple voltage is used as the ramp voltage required by the hysteresis comparator.
- In some hysteresis control schemes, the ramp voltage can be generated by an artificial network. As a result, the ramp voltage is independent of the output ripple voltage. However, in order to achieve superior output transient responses, the output is connected to the input of the hysteresis comparator through an output feedback divider. The output feedback divider is designed so that the output voltage can be regulated at different values. One drawback of having this output feedback divider is the attenuation introduced by the output feedback divider reduces the output voltage deviation at the feedback input during an output transient event. The reduced voltage deviation consequently results in slower line and load transient responses. As a result of having slower line and load transient responses, more capacitors are needed to hold the output transient responses within specification limits, resulting in more expensive and larger printed circuit board (PCB) area solutions. To solve this issue, a hysteresis control method is proposed as shown in
FIG. 1 . -
FIG. 1 illustrates a schematic diagram of a power converter. Thepower converter 100 is a buck converter comprising aninput filter capacitor 101, a high-side switch 102, a low-side switch 103, anoutput inductor 104 and anoutput filtering capacitor 105. The hysteresis controller of thepower converter 100 comprises aresistor 111, acapacitor 108, ahysteresis comparator 112 and adriving circuit block 113. The hysteresis controller of thepower converter 100 further comprises an output feedbackdivider comprising resistors capacitor 110. The REF voltage shown inFIG. 1 is a constant reference voltage. The output voltage (VOUT) of thepower converter 100 can be expressed by the following equation: -
- In Equation (1), R106 is the resistance value of the
resistor 106. R107 is the resistance value of theresistor 107. - The slow output transient response issue is resolved by adding the
capacitor 110. In operation, thecapacitor 110 functions as a feedforward capacitor to pass the output voltage deviation directly to the inverting input of thehysteresis comparator 112 without any attenuation. In addition, thecapacitor 110 also withstands the DC voltage difference between the output VOUT and the feedback node FB. Theresistor 109 provides a DC path for the leakage current flowing out of the inverting input of thecomparator 112. Furthermore, theresistor 109 and thecapacitors hysteresis comparator 112. - The hysteresis control method shown in
FIG. 1 has three drawbacks. First, the capacitance of thecapacitor 110 must be larger than that of thecapacitor 108 to avoid a capacitor divider effect when the output voltage deviation is fed into thecomparator 112 during an output load transient event. Larger capacitance means more silicon area, extra power consumption and complexity. Second, both VOUT and FB inputs are required in the hysteresis control method shown inFIG. 1 . This control system configuration is not compatible with the most popular control scheme (e.g., voltage mode control, current mode control and constant-on time control) in which the FB input is the only required input. Third, the voltage drop across the inductor DC resistance (DCR) of the output inductor due to the output load current presents at thecapacitor 108. This means that during an output load transient response, the average voltage of thecapacitor 108 varies depending on different output load currents. The variation of the voltage across thecapacitor 108 has an impact on the voltage at the inverting input of thehysteresis comparator 112. Such a voltage variation at the inverting input of thehysteresis comparator 112 can affect the output transient response of thepower converter 100. - Accordingly, what needed in the art is a control apparatus that has only the FB input to set the output voltage at different values for different applications such as Pulse Width Modulation (PWM) applications, Pulse Frequency Modulation (PFM) applications and the like. Meanwhile, the control apparatus is able to achieve the same or similar output transient responses as discussed above with respect to
FIG. 1 . - These and other problems are generally solved or circumvented, and technical advantages are generally achieved, by preferred embodiments of the present disclosure which provide a hysteresis control apparatus and method for a buck converter.
- In accordance with an embodiment, an apparatus comprises a PWM ramp generator coupled between a switching node of a power converter and a first input of a comparator, the PWM ramp generator comprising a first resistor and a first capacitor connected in series between the switching node and the first input of the comparator, and a second resistor and a second capacitor connected in parallel between the first input of the comparator and a feedback node, and a PFM control circuit comprising an error amplifier and a current zero crossing detection comparator, wherein the error amplifier is coupled between a second input of the comparator and a reference node, and the PFM control circuit is configured to generate gate drive signal for the power converter when the power converter is configured to operate in a PFM mode.
- In accordance with another embodiment, a method comprises in a PWM mode of a power converter, configuring a plurality of control switches such that gate drive signals of the power converter are generated based on a comparison between an output of a PWM ramp generator and a predetermined reference, and in a PFM mode of the power converter, configuring the plurality of control switches such that gate drive signals of the power converter are generated based on signals generated by an error amplifier and a current zero crossing detection comparator.
- In accordance with yet another embodiment, a system comprises a high-side switch and a low-side switch connected in series between an input voltage bus and ground, wherein a common node of the high-side switch and the low-side switch is a switching node, an inductor connected between the common node of the high-side switch and the low-side switch and an output of the system, a PWM ramp generator coupled between the switching node and a first input of a comparator, the PWM ramp generator comprising a first resistor and a first capacitor connected in series between the switching node and the first input of the comparator, and a second resistor and a second capacitor connected in parallel between the first input of the comparator and a feedback node, and a PFM control circuit comprising an error amplifier and a current zero crossing detection comparator, wherein the error amplifier is coupled between a second input of the comparator and a reference node, and the PFM control circuit is configured to generate gate drive signal for the system when the system is configured to operate in a PFM mode.
- The foregoing has outlined rather broadly the features and technical advantages of the present disclosure in order that the detailed description of the disclosure that follows may be better understood. Additional features and advantages of the disclosure will be described hereinafter which form the subject of the claims of the disclosure. It should be appreciated by those skilled in the art that the conception and specific embodiment disclosed may be readily utilized as a basis for modifying or designing other structures or processes for carrying out the same purposes of the present disclosure. It should also be realized by those skilled in the art that such equivalent constructions do not depart from the spirit and scope of the disclosure as set forth in the appended claims.
- For a more complete understanding of the present disclosure, and the advantages thereof, reference is now made to the following descriptions taken in conjunction with the accompanying drawings, in which:
-
FIG. 1 illustrates a schematic diagram of a power converter; -
FIG. 2 illustrates a power converter and the associated PWM and PFM control circuits in accordance with various embodiments of the present disclosure; -
FIG. 3 illustrates a schematic diagram of the power converter shown inFIG. 2 when the power converter is configured to operate in a PWM mode in accordance with various embodiments of the present disclosure; -
FIG. 4 illustrates various signals associated with the power converter shown inFIG. 3 in accordance with various embodiments of the present disclosure; -
FIG. 5 illustrates a gain versus frequency response curve of the feedback divider network in accordance with various embodiments of the present disclosure; -
FIG. 6 illustrates a gain versus frequency response curve of an error amplifier having a dominant pole in accordance with various embodiments of the present disclosure; -
FIG. 7 illustrates various signals associated with the error amplifier shown inFIG. 6 in accordance with various embodiments of the present disclosure; -
FIG. 8 illustrates a first implementation of the PFM control circuit in accordance with various embodiments of the present disclosure; -
FIG. 9 illustrates various voltage and current signals associated with the first implementation of the PFM control circuit shown inFIG. 8 in accordance with various embodiments of the present disclosure; -
FIG. 10 illustrates a second implementation of the PFM control circuit in accordance with various embodiments of the present disclosure; -
FIG. 11 illustrates various voltage and current signals associated with the second implementation of the PFM control circuit shown inFIG. 10 in accordance with various embodiments of the present disclosure; -
FIG. 12 illustrates a third implementation of the PFM control circuit in accordance with various embodiments of the present disclosure; -
FIG. 13 illustrates various voltage and current signals associated with the third implementation of the PFM control circuit shown inFIG. 12 in accordance with various embodiments of the present disclosure; and -
FIG. 14 illustrates a flow chart of a control method for operating the power converter shown inFIG. 2 in accordance with various embodiments of the present disclosure. - Corresponding numerals and symbols in the different figures generally refer to corresponding parts unless otherwise indicated. The figures are drawn to clearly illustrate the relevant aspects of the various embodiments and are not necessarily drawn to scale.
- The making and using of the presently preferred embodiments are discussed in detail below. It should be appreciated, however, that the present disclosure provides many applicable inventive concepts that can be embodied in a wide variety of specific contexts. The specific embodiments discussed are merely illustrative of specific ways to make and use the disclosure, and do not limit the scope of the disclosure.
- The present disclosure will be described with respect to preferred embodiments in a specific context, namely a hysteresis control apparatus and method for a buck converter. The invention may also be applied, however, to a variety of power conversion systems. Hereinafter, various embodiments will be explained in detail with reference to the accompanying drawings.
-
FIG. 2 illustrates a power converter and the associated PWM and PFM control circuits in accordance with various embodiments of the present disclosure. The power converter is a buck converter comprising aninput filter capacitor 201, a high-side switch 202, a low-side switch 203, anoutput inductor 204 and anoutput filtering capacitor 205. As shown inFIG. 2 , the high-side switch 202 and the low-side switch 203 are connected in series between an input voltage bus and ground. A common node of the high-side switch 202 and the low-side switch 203 is the switching node (SW as shown inFIG. 2 ) of the power converter. Theoutput inductor 204 is connected between the common node of the high-side switch 202 and the low-side switch 203, and an output of the power converter. - The control circuit of the power converter shown in
FIG. 2 comprises aPWM ramp generator 210, aPFM control circuit 250, acomparator 215, a feedback divider, and control logic andgate drive circuits 216. - In some embodiments, the
comparator 215 is implemented as a hysteresis comparator. Thecomparator 215 is configured to generate a control signal fed into the control logic andgate drive circuits 216. - As shown in
FIG. 2 , the feedback divider is formed byresistors resistors capacitor 208 is connected in parallel with theresistor 206. Thecapacitor 208 functions as a feedforward capacitor. - As shown in
FIG. 2 , thePWM ramp generator 210 is coupled between the switching node SW of the power converter and a first input of thecomparator 215. More particularly, thePWM ramp generator 210 is connected to the switching node SW through a third control switch S3. - The
PWM ramp generator 210 comprises afirst resistor 211 and afirst capacitor 212 connected in series between the third control switch S3 and the first input of thecomparator 215. The first input is an inverting input of thecomparator 215. ThePWM ramp generator 210 further comprises asecond resistor 214 and asecond capacitor 213 connected in parallel between the first input of thecomparator 215 and the feedback node FB. - As shown in
FIG. 2 , thePFM control circuit 250 comprises anerror amplifier 230 and a current zerocrossing detection comparator 220. Theerror amplifier 230 is coupled between a second input of thecomparator 215 and a reference node REF. The second input is a non-inverting input of thecomparator 215. ThePFM control circuit 250 is configured to generate gate drive signal for the power converter when the power converter is configured to operate in a PFM mode. - It should be noted that the block diagram of the
PFM control circuit 250 shown inFIG. 2 merely includes basic function units of thePFM control circuit 250. Depending on different PFM control schemes, the structure of thePFM control circuit 250 may vary accordingly. In some embodiments, a threshold voltage generator may be coupled between the non-inverting input of thecomparator 215 and theerror amplifier 230. The detailed implementation of this PFM control scheme will be described below with respect toFIGS. 8-9 . In alternative embodiments, a peak current detection comparator may be employed to determine the on-time of the high-side switch 202. The detailed implementation of this PFM control scheme will be described below with respect toFIGS. 10-11 . In alternative embodiments, a constant on-time generator may be employed to determine the on-time of the high-side switch. The detailed implementation of this PFM control scheme will be described below with respect toFIGS. 12-13 . - Three control switches are employed to change the control circuit configuration depending on different operating modes. As shown in
FIG. 2 , a first control switch S1 is connected between the first input of thecomparator 215 and the feedback node FB. A second control switch S2 is connected between the second input of thecomparator 215 and the reference node REF. The third control switch S3 is connected between the switching node SW and thefirst resistor 211. In operation, the second switch S2 and the third switch S3 are configured to be turned on, and the first switch S1 is configured to be turned off when the power converter is configured to operate in a PWM mode. On the other hand, the second switch S2 and the third switch S3 are configured to be turned off, and the first switch S1 is configured to be turned on when the power converter is configured to operate in the PFM mode. It should be noted that depending on design needs, the third switch S3 can be placed any location between the switching node SW and the first input of thecomparator 215. In other words, the third switch S3 is coupled between the switching node SW and the first input of thecomparator 215. It should further be noted that depending on design needs, the locations of thefirst resistor 211 and thefirst capacitor 212 can be swapped. - In some embodiments, a resistor-capacitor filter (not shown) may be connected to the switching node SW. In operation, the resistor-capacitor filter is configured such that an output voltage of the resistor-capacitor filter is used to determine an output voltage of the power converter when the power converter is configured to operate in the PFM mode during an initial power up period. Vo can be used, together with the input voltage, to determine the output value of the constant-on-time generator used in the constant-on time PFM control.
- In some embodiments, the
PWM ramp generator 210, three control switches S1-S3, thecomparator 215, thePFM control circuit 250 and the control logic andgate drive circuits 216 may be integrated into a single IC device or on a printed circuit board. In alternative embodiments, the power switches 202 and 203 may be integrated into this single IC device too. - In the PWM mode operation, the
PWM ramp generator 210 generates a saw-tooth like ramp voltage on top of the voltage on the FB node. The sum of the saw-tooth like ramp voltage and the voltage on the FB node is compared with the REF voltage to control the on and off time intervals of the power switches 202 and 203, thereby regulating the output voltage of the power converter within the specification limits. - In the PWM mode operation, only the ramp voltage across the
capacitor 213 is used to determine the on and off time intervals of the power switches 202 and 203. Thecapacitor 208 is introduced to pass the output voltage deviation from VOUT to the feedback node FB, and then to the inverting input of thehysteresis comparator 215 with very little attenuation, resulting good output transient responses as well as good DC regulation. The capacitance value of thecapacitor 208 is chosen such that the impedance formed by theresistor 206 and thecapacitor 208 is much smaller than the impedance formed by thecapacitor 213 andresistor 214 at the interested switching frequencies. In some embodiments, the impedance formed byresistor 214 and capacitor 213is at least five times greater than the impedance formed by theresistor 206 and thecapacitor 208. - As shown in
FIG. 2 , the DC voltage difference between VOUT and the feedback node FB drops acrossresistors capacitors capacitor 213 and theresistor 214 are connected in parallel, the DC impedance of these two is determined by theresistor 214. Theresistor 211 and thecapacitor 212 are connected in series. The DC impedance of these two is determined by thecapacitor 212. Furthermore, if theresistors resistor 211 is much larger (e.g., 211 is 10× larger than 214) than that of theresistor 214, the majority of the DC voltage difference between the VOUT node and the feedback node FB drops across thecapacitor 212. This relationship has nothing to do with the capacitance of thecapacitor 212. For example, this relationship is still valid when the capacitance of thecapacitor 212 can be even smaller than that of thecapacitor 213. - One advantageous feature of having the power converter shown in
FIG. 2 is that all control components can be integrated into a single IC device. Furthermore, most of the voltage across the DCR of the output inductor due to the output current also drops across thecapacitor 212 at steady state. During an output load transient event, when the output current varies, the voltage across the DCR of the output inductor varies too. The voltage across thecapacitor 212 cannot change instantaneously. Therefore, the varying voltage drops across theresistors resistor 214 is much smaller than that of theresistor 211, the majority of the varying voltage drops across theresistor 211. Thus, the voltage level at the inverting input of thehysteresis comparator 215 maintains relatively constant. In comparison with the control circuit shown inFIG. 1 , one skilled the art would understand thecapacitor 212 is not in the path between the output node VOUT and the inverting input of thehysteresis comparator 215 during an output load transient event. Thus, thecapacitor 212 does not cause a capacitor divider effect. -
FIG. 3 illustrates a schematic diagram of the power converter shown inFIG. 2 when the power converter is configured to operate in a PWM mode in accordance with various embodiments of the present disclosure. Once the power converter shown inFIG. 2 is configured to operate in the PWM mode, control switches S2 and S3 shown inFIG. 2 are turned on, and control switch S1 is turned off. The circuit shown inFIG. 2 can be simplified as the circuit shown inFIG. 3 . - As shown in
FIG. 3 , thePWM ramp generator 210 comprises afirst resistor 211 and afirst capacitor 212 connected in series between the switching node SW and the inverting input of thecomparator 215. ThePWM ramp generator 210 further comprises asecond resistor 214 and asecond capacitor 213 connected in parallel between the inverting input of thecomparator 215 and the feedback node FB. Theresistor 214 provides a path for the leakage current flowing out of the inverting input of thecomparator 215. Furthermore, theresistor 214 can eliminate the effect of the voltage divider formed bycapacitors capacitor 212 regardless of the capacitance value of thecapacitor 212. - In operation, the
resistors capacitors comparator 215. In particular, the voltage on the switching node SW is pulled up to the input voltage VIN after the high-side switch 202 is turned on. The voltage on the switching node SW is pulled down to ground after the high-side switch 202 is turned off and the low-side switch 203 is turned on. When the voltage on the switching node SW is pulled up to VIN, thecapacitor 213 is charged by the voltage on SW through theresistor 211 and thecapacitor 212. When the voltage on the switching node SW is pulled down to ground, thecapacitor 213 is discharged through theresistor 211 and thecapacitor 212. As a result, a ramp voltage VRAMP is generated across thecapacitor 213. - Furthermore, the voltage across the
capacitor 213 is connected to the feedback node FB. When the feedback voltage on the feedback node FB moves up and down, the voltage at the inverting input of thecomparator 215 moves up and down accordingly. In some embodiments, the capacitance of thecapacitor 208 is much larger than that of thecapacitor 213. Since the capacitor value of thecapacitor 208 is much larger than that ofcapacitor 213, any voltage deviation at VOUT is passed to the feedback node FB through thecapacitor 208 with little attenuation. This feature helps thepower converter 200 archive a fast transient response during an output transient event. - The amplitude of the ramp voltage VRAMP across the
capacitor 213 can be adjusted by adjusting a time constant. The time constant τ is given by the following equation: -
- In Equation (2), R211 is the resistance of the
resistor 211. R214 is the resistance of theresistor 214. C213 is the capacitance of thecapacitor 213. In some embodiments, the time constant τ should be much larger than the interested PWM switching period. For example, the time constant τ is at least five times greater than the interested PWM switching period. - The time constant determined by Equation (2) determines the gain of the hysteresis comparator. The gain has an impact on the stability of the close loop performance of the
power converter 200. Once the values ofresistors capacitors capacitor 213 is function of the input voltage and the output voltage. The amplitude changes for different input and output voltages are independent of the output load current. - In some embodiments, the voltage REF at the non-inverting input of the
comparator 215 includes a square waveform (not shown but illustrated inFIG. 4 ). The peak and valley values of the square waveform represent the trigger thresholds of thecomparator 215 to turn on and turn off the high-side switch 202, respectively. The difference between the peak and valley values of the square waveform represents the hysteresis of thecomparator 215. This difference determines the switching frequency of thepower converter 200. The threshold (i.e. the difference between the peak and valley values) can be adjusted to obtain a constant switching frequency over a wide input and/or output voltage range. - It should be noted that if under the hysteresis control, the
power converter 200 is required to operate in a constant switching frequency, a phase lock loop (PLL) circuit can be employed to adjust the difference between the peak and valley values of the REF voltage to keep the switching frequency constant over a wide input and/or output voltage range. -
FIG. 4 illustrates various signals associated with the power converter shown inFIG. 3 in accordance with various embodiments of the present disclosure. The horizontal axis represents intervals of time. There are six rows. The first row represents the output voltage of the power converter shown inFIG. 3 . The second row represents the ramp voltage VRAMP and the reference voltage REF. The solid line of the second row represents the ramp voltage VRAMP. The dotted line represents the square waveform portion of the reference voltage REF. The third row represents the current IL flowing through the inductor of the power converter. The fourth row represents the output voltage (Vc) of thecomparator 215. The fifth row represents the gate drive signal VGS1 of the high-side switch of the power converter. The sixth row represents the gate drive signal VGS2 of the low-side switch of the power converter. - At t1, the high-
side switch 202 is turned on. The reference voltage REF jumps from a valley value to a peak value. From t1 to t2, the high-side switch 202 is on. Thecapacitor 213 is charged by the input voltage VIN, which is applied to the switching node SW once the high-side switch 202 is on. At t2, since the voltage at the inverting input of thecomparator 215 reaches the peak value of the reference voltage REF, thecomparator 215 triggers. The output of thecomparator 215 generates signals to turn off the high-side switch 202, and turn on the low-side switch 203 through the control logic andgate drive circuits 216. At t2, the reference voltage REF switches back to its valley value to keep the output status of thecomparator 215. - During the time interval (from t2 to t3) in which the low-
side switch 203 is on, the switching node SW is pulled down to ground by the low-side switch 203. Thecapacitor 213 is discharged and the voltage at the inverting input of thecomparator 215 decreases. At t3, the voltage at inverting input reaches the valley value of the reference voltage REF. In response to this, thecomparator 215 triggers. The output of thecomparator 215 generates signals to turn off the low-side switch 203, and turn on the high-side switch 202 through the control logic andgate drive circuits 216. At t3, the switching cycles repeats as shown inFIG. 4 . - In operation, various voltage deviations may occur at the output of the
power converter 200. The voltage deviations are caused by either a line transient or an output load transient. Depending on different operating conditions, the voltage deviation may be either an overshoot or an undershoot. Furthermore, the voltage deviation may occur in any time durations shown inFIG. 4 (e.g., from t1 to t2 or from t2 to t3). The control circuit shown inFIG. 3 is able to provide a fast transient response to maintain the output voltage within specification limits. The discussion below explains how the control circuit shown inFIG. 3 is able to provide a fast transient response under different voltage deviations. - In operation, if the voltage deviation is in an undershoot condition, and the high-
side switch 202 is on (from t1 to t2), the voltage deviation causes the voltage at the inverting input of thecomparator 215 to decrease. As shown inFIG. 4 , the decreased voltage at the inverting input of thecomparator 215 increases the conduction time of the high-side switch 202. The increased conduction time of the high-side switch 202 helps to increase the output voltage, thereby reducing the voltage deviation. On the other hand, if the voltage deviation is in an undershoot condition, and the low-side switch 203 is on (from t2 to t3), the voltage deviation causes a voltage dip at the inverting input of thecomparator 215. According to the operating principle shownFIG. 4 , the voltage dip at the inverting input of thecomparator 215 shortens the conduction time of the low-side switch 203. The reduced conduction time of the low-side switch 203 helps to increase the output voltage, thereby reducing the voltage deviation. - In operation, if the voltage deviation is in an overshoot condition, and the high-
side switch 202 is on (from t1 to t2), the voltage deviation causes the voltage at the inverting input of thecomparator 215 to increase. According to the operating principle shownFIG. 4 , the increased voltage at the inverting input of thecomparator 215 reduces the conduction time of the high-side switch 202. The reduced conduction time of the high-side switch 202 helps to reduce the output voltage, thereby reducing the voltage deviation. On the other hand, if the voltage deviation is in an overshoot condition, and the low-side switch 203 is on (from t2 to t3), the voltage deviation causes a voltage overshoot at the inverting input of thecomparator 215. According to the operating principle shownFIG. 4 , the voltage overshoot at the inverting input of thecomparator 215 increases the conduction time interval of the low-side switch 203. The increased conduction time of the low-side switch 203 helps to reduce the output voltage, thereby reducing the voltage deviation. - From the description above, one skilled in the art can draw the conclusion that the
power converter 200 under the hysteresis control can response to the output voltage deviation instantly regardless of which switch (switch 202 or switch 203) is on at the time when the deviation event occurs. In comparison with the power converter shown inFIG. 1 , thepower converter 200 shown inFIG. 3 is able to provide the fastest output transient response and the control circuit of thepower converter 200 can be integrated in one single IC. - In some applications, the power converter may be configured to operate in a very light load condition. In the light load condition, the power converter is configured to operate in the PFM mode to reduce power losses. In the PFM mode, an error amplifier is employed to improve the performance of the control circuit.
FIGS. 5-6 below explain why a dominant pole error amplifier is employed in the PFM mode. -
FIG. 5 illustrates a gain versus frequency response curve of the feedback divider network in accordance with various embodiments of the present disclosure. The outputfeedback divider network 300 is shown in the dashedrectangle 550. Theresistors -
- In Equation (3), R301 is the resistance value of the
resistor 301. R302 is the resistance value of theresistor 302. The feedback node FB is connected to a first input of an error amplifier. REF is connected to a second input of the error amplifier. REF is a predetermined reference voltage. - The
capacitor 303 helps the control circuit improve the output transient response. The gain of the voltage at FB node over the output voltage VOUT is expressed by the following equation: -
- The gain in Equation (4) is plotted in the dashed
rectangle 560. As shown inFIG. 5 , the attenuation provided byresistors - In the traditional PFM operation of a hysteresis controller, the output ripple voltage is fed into the inverting input of the comparator directly. Such an implementation is simple and effective. However, this implementation cannot be operated with an output of the feedback divider. As shown in
FIG. 5 , the gain at a frequency less than 10 kHz is about 0.17. This means that a 20-mV ripple voltage at the output VOUT can generate a voltage deviation of about 20 mV at the feedback node FB without any attenuation when the PFM switching frequency is 1 Megahertz. In contrast, a 20-mV ripple voltage at the output VOUT can generate a voltage deviation of about 3.4 mV at the feedback node FB with attenuation when the PFM switching frequency is 10 kHz. Such a small output ripple voltage at the feedback node FB fed to the inverting input of the comparator may cause a false trigger, thereby resulting in frequency jittering and irregular output ripple voltages. To solve false trigger issue, a voltage error amplifier having a dominant pole is introduced to improve the performance of the power converter in the PFM mode. -
FIG. 6 illustrates a gain versus frequency response curve of an error amplifier having a dominant pole in accordance with various embodiments of the present disclosure. The error amplifier having a dominant pole is illustrated in the dashedrectangle 650. In some embodiments, the error amplifier is implemented as a transconductanceoperational amplifier 403. Aresistor 402 and acapacitor 401 are connected in parallel between the output of theerror amplifier 403 and ground. The frequency of the dominant pole is determined by the product of the capacitance of thecapacitor 401 and the resistance of theresistor 402. The DC gain is determined by the product of Gm (the gain of the transconductance operational amplifier) and the resistance of theresistor 402. The gain of the voltage VER at the output of the error amplifier over the voltage VFB at the feedback node FB is expressed by the following equation: -
- The gain is plotted in the dashed
rectangle 660. As shown inFIG. 6 , the gain is very high (about 70 dB) when the frequency is less than 10 Hz, and the gain is below 0 dB when frequency is above 100 kHz. The gain shown inFIG. 6 indicates the voltage on the feedback node FB is amplified if the switching frequency is less than 100 kHz. The voltage on the feedback node FB is attenuated if the frequency is above 100 kHz. Theerror amplifier 403 shown inFIG. 6 will be used in the PFM operation, which will be discussed below with respect toFIGS. 8-13 . - It should be noted that the dominant pole of the
error amplifier 403 should be designed such that a 0 dB frequency is higher than the pole frequency formed by a feedback divider (e.g., the pole formed byresistors feedforward capacitor 508 shown inFIG. 8 ). -
FIG. 7 illustrates various signals associated with the error amplifier shown inFIG. 6 in accordance with various embodiments of the present disclosure. The horizontal axis represents intervals of time. There are three rows. The first row represents the output voltage of the power converter. The second row represents the voltage VFB on the feedback node FB. The third row represents the voltage VER at the output of the error amplifier. - As shown in
FIG. 7 , the error amplifier is able to improve the noise immunity of the FPM hysteresis comparator if the ripple voltage on the feedback node FB is compared with the output voltage of the voltage error amplifier at a low PFM operating frequency. As shown inFIG. 7 , from t1 to t2, the output voltage of the voltage error amplifier may drop below a predetermined clamping point. In order to improve the output transient responses during the PFM mode operation, an active clamp (not shown) can be used to prevent the output of the error amplifier from going too low at a very low frequency. For example, from t1 to t2, the output of the error amplifier is clamped so as to keep the output of the error amplifier over a predetermined clamping point (Clamp shown inFIG. 7 ). -
FIG. 8 illustrates a first implementation of the PFM control circuit in accordance with various embodiments of the present disclosure. Referring back toFIG. 2 , when the power converter is configured to operate in the PFM mode, S2 and S3 shown inFIG. 2 are turned off, and S1 is turned on. The circuit shown inFIG. 2 can be simplified as the circuit shown inFIG. 8 . In the first implementation of the PFM control circuit, athreshold voltage generator 515 is added into the PFM control circuit. As shown inFIG. 8 , thethreshold voltage generator 515 is coupled between the second input of thecomparator 513 and an output of theerror amplifier 514. As shown inFIG. 8 , the function units in the dashedrectangle 510 are the PFM control circuit of thepower converter 500. - As shown in
FIG. 8 , thepower converter 500 comprises a buck power stage, an output feedback divider, and the PFM control circuit. The buck power stage comprises aninput filtering capacitor 501, power switches 502, 503, anoutput inductor 504 and anoutput filter capacitor 505. The output feedback divider comprisesresistors feedforward capacitor 508. The PFM control circuit comprises control logic andgate drive circuits 511, a current zerocrossing detection comparator 512, acomparator 513, athreshold voltage generator 515 and anerror amplifier 514. - In some embodiments, the
error amplifier 514 is a transconductance operation amplifier having a dominant pole such as the error amplifier shown inFIG. 6 . Referring back toFIG. 6 , thecapacitor 401 and theresistor 402 are connected in parallel between the output of the error amplifier and ground. Thecapacitor 401 and theresistor 402 form the dominant pole. - In some embodiments, a non-inverting input of the
error amplifier 514 is connected to a predetermined reference REF. An inverting input of theerror amplifier 514 is connected to the feedback node as shown inFIG. 6 . - In operation, a comparison of a voltage VFB on the feedback node, and a sum of an output voltage VER of the
error amplifier 514 and a threshold voltage VTH from thethreshold voltage generator 515 is used to determine an on-time of the high-side switch 502 of thepower converter 500. A comparison of the voltage VFB on the feedback node and the output voltage VER of theerror amplifier 514 is used to determine a turn-on instant of the high-side switch 502 of thepower converter 500. The current zerocrossing detection comparator 512 is configured to determine an on-time of the low-side switch 503 of thepower converter 500 once a current flowing through the low-side switch of the power converter reaches zero. -
FIG. 9 illustrates various voltage and current signals associated with the first implementation of the PFM control circuit shown inFIG. 8 in accordance with various embodiments of the present disclosure. The horizontal axis represents intervals of time. There are ten rows. The first row represents the output voltage of the power converter shown inFIG. 8 . The second row represents the current I_Q1 flowing through the high-side switch of the power converter. The third row represents the current I_Q2 flowing through the low-side switch of the power converter. The fourth row represents the current IL flowing through the inductor of the power converter. The fifth row represents the signal V1 shown inFIG. 8 . The sixth row represents the signal V2 shown inFIG. 8 . The seventh row represents the signal V3 shown inFIG. 8 . The eighth row represents the output voltage VER of the error amplifier and the voltage VFB on the feedback node. The solid line is VER, and the dashed line is VFB. The ninth row represents the gate drive signal VGS1 of the high-side switch of the power converter. The tenth row represents the gate drive signal VGS2 of the low-side switch of the power converter. - In operation, during the time interval (from t1 to t2) in which the high-
side switch 502 is on, the inductor current IL is charged from zero, and the output ripple voltage increases. In response to the increased output ripple voltage, the voltage on the feedback node FB increases too. Since the voltage on the feedback node FB is fed into the inverting input of the error amplifier (shown inFIG. 6 ), the output voltage VER of the voltage error amplifier decreases. Once the voltage on the feedback node FB increases to a certain value at which the voltage at the inverting input of thecomparator 513 exceeds the sum of the threshold voltage VTH and the output voltage VER of the voltage error amplifier, the output of thecomparator 513 triggers (from a logic high state to a logic low state). In response to this logic state change, the logic signal V1 flips from a logic high state to a logic low state at t2. The logic signal V3 flips from a logic low state to a logic high state at t2. - In response to the changes of the logic signals V1 and V3, the control logic and
gate drive circuits 511 turn off the high-side switch 502 and turn on the low-side switch 503 at t2 as shown inFIG. 9 . Once the low-side switch 503 is turned on, the current zerocrossing detection comparator 512 is enabled to monitor the current (I_Q503) flowing through the low-side switch 503, and the logic signal V2 changes from a logic low state to a logic high state at t2. Once the current flowing through the low-side switch 503 reaches zero (IZC_REF) as shown inFIG. 8 , the logic signal V2 changes from a logic high state to a logic low state at t3. This logic state change of V2 causes the control logic andgate drive circuits 511 to turn off the low-side switch 503 at t3, and keep the high-side switch 502 off as shown inFIG. 9 . - At t3, the threshold voltage from the
threshold voltage generator 515 is removed. In other words, the output of the voltage error amplifier is connected to the comparator directly. During the time interval from t3 to t4, bothswitches output capacitor 505. - At t4, the voltage (VFB) at the inverting input of the
comparator 513 reaches the output voltage of the voltage error amplifier. As shown inFIG. 9 , the control logic signal V3 flips from a logic high state to a logic low state. The control logic signal V1 flips from a logic low state to a logic high state. These two logic state changes cause the control logic andgate drive circuits 511 to turn on the high-side switch 502, and keep the low-side switch 503 off. At t4, the hysteresis threshold from thethreshold voltage generator 515 is added on top of the output voltage of theerror amplifier 514. The output voltage of the power converter starts to increase. Once the output voltage of the power converter increases to a certain value such that the voltage at the inverting input is equal to the voltage at the non-inverting input of thecomparator 513, thecomparator 513 triggers again, and the operation cycle repeats as shown inFIG. 9 . - It should be noted that the threshold voltage VTH can be adjusted to control the energy delivered to the output over each PFM switching cycle. The amount of energy delivered to the output over one PFM cycle also determines the peak-to-peak output ripple voltage in the PFM mode operation.
- In operation, when a voltage deviation occurs at the output of the power converter, the voltage at FB node changes accordingly. In some embodiments, the output voltage deviation is in an undershoot condition, and the output voltage deviation occurs at the time interval (e.g., from t3 to t4) when both
switches comparator 513 low to cross the voltage at the non-inverting input of thecomparator 513. According to the operating principle shown inFIG. 9 , thecomparator 513 triggers to turn on the high-side switch 502 to deliver the energy from the input to the output to hold the output voltage in regulation. - In alternative embodiments, the output undershoot event occurs at the time interval (e.g., from t1 to t2) when the high-
side switch 502 is on. The voltage dip at the inverting input of thecomparator 513 increases the time to reach the voltage at non-inverting input of thecomparator 513. As a result, the high-side switch 502 remains on for a longer time to deliver more energy from the input to the output to keep the output voltage in regulation. - In some embodiments, the output voltage deviation is in an overshoot condition, and the output voltage deviation occurs at the time interval (e.g., from t3 to t4) when both
switches comparator 513 to increase. The increased voltage at the inverting input of thecomparator 513 causes a delayed trigger. Thus, bothswitches - In alternative embodiments, the output overshoot event occurs at the time interval (e.g., from t1 to t2) when the high-
side switch 502 is on. The overshoot causes the voltage at the inverting input of thecomparator 513 to increase. The increased voltage at the inverting input of thecomparator 513 causes an early trigger of thecomparator 513. The early trigger turns off the high-side switch 502 to reduce the energy delivered to the output over one PFM switching cycle, thereby maintaining the output voltage in regulation. - It should be noted that the transient responses described above may result in the frequency change of the PFM mode.
- From the description above, one skilled in the art would recognize the voltage threshold VTH determines the amount of energy deliver to the output of the power converter over one PFM switching cycle. The voltage threshold VTH also determines the peak-to-peak output ripple voltage during the PFM operation. The threshold voltage VTH can be adjusted based on the input voltage and the output voltage to keep the output ripple voltage in the PFM mode relatively constant.
-
FIG. 10 illustrates a second implementation of the PFM control circuit in accordance with various embodiments of the present disclosure. Referring back toFIG. 2 , when the power converter is configured to operate in the PFM mode, S2 and S3 shown inFIG. 2 are turned off, and S1 is turned on. The circuit shown inFIG. 2 can be simplified as the circuit shown inFIG. 10 . In the second implementation of the PFM control circuit, a peakcurrent detection comparator 615 is added into the PFM control circuit. As shown inFIG. 10 , the peakcurrent detection comparator 615 is configured to receive the current (I_Q602) flowing through the high-side switch 602 and a predetermined peak current reference IPK_REF. As shown inFIG. 10 , the function units in the dashedrectangle 610 are the PFM control circuit of thepower converter 600. - As shown in
FIG. 10 , thepower converter 600 comprises a buck power stage, an output feedback divider, and the PFM control circuit. The buck power stage comprises aninput filtering capacitor 601, power switches 602, 603, anoutput inductor 604 and anoutput filter capacitor 605. The output feedback divider comprisesresistors feedforward capacitor 608. The PFM control circuit comprises control logic andgate drive circuits 611, a current zerocrossing detection comparator 612, acomparator 613, a peakcurrent detection comparator 615 and anerror amplifier 614. - In some embodiments, the
error amplifier 614 is a transconductance operation amplifier having a dominant pole such as the error amplifier shown inFIG. 6 . Referring back toFIG. 6 , thecapacitor 401 and theresistor 402 are connected in parallel between the output of the error amplifier and ground. Thecapacitor 401 and theresistor 402 form the dominant pole. - In operation, a comparison of a current of the high-side switch 602 (I_Q602) and the peak current reference IPK_REF at the peak
current detection comparator 615 is used to determine an on-time of the high-side switch 602 of thepower converter 600. A comparison of the voltage on the feedback node and the output voltage of the error amplifier is used to determine a turn-on instant of the high-side switch 602 of thepower converter 600. The current zerocrossing detection comparator 612 is configured to determine an on-time of the low-side switch 603 of thepower converter 600 once a current flowing through the low-side switch of the power converter reaches zero. -
FIG. 11 illustrates various voltage and current signals associated with the second implementation of the PFM control circuit shown inFIG. 10 in accordance with various embodiments of the present disclosure. The horizontal axis represents intervals of time. There are ten rows. The first row represents the output voltage of the power converter shown inFIG. 10 . The second row represents the current I_Q1 flowing through the high-side switch of the power converter. The third row represents the current I_Q2 flowing through the low-side switch of the power converter. The fourth row represents the current IL flowing through the inductor of the power converter. The fifth row represents the signal V1 shown inFIG. 10 . The sixth row represents the signal V2 shown inFIG. 10 . The seventh row represents the signal V3 shown inFIG. 10 . The eighth row represents the output voltage VER of the error amplifier and the voltage VFB on the feedback node. The solid line is VER, and the dashed line is VFB. The ninth row represents the gate drive signal VGS1 of the high-side switch of the power converter. The tenth row represents the gate drive signal VGS2 of the low-side switch of the power converter. - In operation, during the time interval (from t1 to t2) in which the high-
side switch 602 is on, the inductor current IL is charged from zero, and the output ripple voltage increases. In response to the increased output ripple voltage, the voltage on the feedback node FB increases too. Since the voltage on the feedback node FB is fed into the inverting input of the error amplifier (shown inFIG. 6 ), the output voltage of the voltage error amplifier decreases. Once the output inductor current reaches a pre-determined threshold IPK_REP, the peakcurrent detection comparator 615 triggers at t2 and generates a short low pulse at the control logic signal V1 (from a logic high state to a logic low state at t2). In response to this short low pulse, the control logic andgate drive circuits 611 turn off the high-side switch 602 and turn on the low-side switch 603 at t2 as shown inFIG. 11 . - Once the low-
side switch 603 is turned on, the current zerocrossing detection comparator 612 is enabled to monitor the current (I_Q603) flowing through the low-side switch 603, and the logic signal V2 changes from a logic low state to a logic high state at t2. Once the current flowing through the low-side switch 603 reaches zero, the logic signal V2 changes from a logic high state to a logic low state at t3. This logic state change of V2 causes the control logic andgate drive circuits 611 to turn off the low-side switch 603 at t3, and keep the high-side switch 602 off as shown inFIG. 11 . - During the time interval from t3 to t4, both
switches output capacitor 605. - At t4, the voltage (VFB) at the inverting input of the
comparator 613 reaches the output voltage of the voltage error amplifier. Thecomparator 613 triggers accordingly. Thecomparator 613 generates a short low pulse at the control logic signal V3. As shown inFIG. 11 , the control logic signal V3 flips from a logic high state to a logic low state at t4. The logic state change of V3 causes the control logic andgate drive circuits 611 to turn on the high-side switch 602, and keep the low-side switch 603 off. The inductor current starts to charge up from zero. Once the inductor current reaches the pre-determined threshold IPK_REP, the peakcurrent detection comparator 615 triggers and generates a short pulse on the control logic signal V1, causing the control logic andgate drive circuits 611 to turn off thepower switch 602 and turn on thepower switch 603. The control logic signal V2 resets from a logic low state to a logic high state, and the zero currentcrossing detection comparator 612 is enabled. The PFM mode switching cycle repeats as shown inFIG. 11 . - It should be noted that the amount of energy delivered to the output can be controlled by controlling the peak inductor current.
- The transient response of the
power converter 600 is very similar to that of thepower converter 500, and hence is not repeated herein. -
FIG. 12 illustrates a third implementation of the PFM control circuit in accordance with various embodiments of the present disclosure. Referring back toFIG. 2 , when the power converter is configured to operate in the PFM mode, S2 and S3 shown inFIG. 2 are turned off, and S1 is turned on. The circuit shown inFIG. 2 can be simplified as the circuit shown inFIG. 12 . In the third implementation of the PFM control circuit, a constant on-time generator 715 is added into the PFM control circuit. As shown inFIG. 12 , the constant on-time generator 715 is configured to receive the input voltage VIN and the sensed output voltage VOUT_S. As shown inFIG. 12 , the function units in the dashedrectangle 710 are the PFM control circuit of thepower converter 700. - In some embodiments, a resistor-capacitor low pass filter is needed to obtain the sensed the output voltage from the SW node since the PFM control circuit does not have any access to the actual output voltage. The output voltage is determined once the output feedback divider is determined and the reference voltage of the voltage error amplifier, REF, is known. Therefore, the output voltage sense can be done each time during the soft start period to detect the output voltage through the SW switching node. There is no need to continue sense the output voltage during the operation.
- As shown in
FIG. 12 , thepower converter 700 comprises a buck power stage, an output feedback divider, and the PFM control circuit. The buck power stage comprises aninput filtering capacitor 701, power switches 702, 703, anoutput inductor 704 and anoutput filter capacitor 705. The output feedback divider comprisesresistors feedforward capacitor 708. The PFM control circuit comprises control logic andgate drive circuits 711, a current zerocrossing detection comparator 712, acomparator 713, a constant on-time generator 715 and anerror amplifier 714. - In some embodiments, the
error amplifier 714 is a transconductance operation amplifier having a dominant pole such as the error amplifier shown inFIG. 6 . Referring back toFIG. 6 , thecapacitor 401 and theresistor 402 are connected in parallel between the output of the error amplifier and ground. Thecapacitor 401 and theresistor 402 form the dominant pole. - In operation, an output of the constant on-
time generator 715 is used to determine an on-time of the high-side switch 702 of thepower converter 700. A comparison of the voltage on the feedback node and the output voltage of the error amplifier is used to determine a turn-on instant of the high-side switch 702 of thepower converter 700. The current zerocrossing detection comparator 712 is configured to determine an on-time of the low-side switch 703 of thepower converter 700 once a current flowing through the low-side switch of the power converter reaches zero. -
FIG. 13 illustrates various voltage and current signals associated with the third implementation of the PFM control circuit shown inFIG. 12 in accordance with various embodiments of the present disclosure. The horizontal axis represents intervals of time. There are ten rows. The first row represents the output voltage of the power converter shown inFIG. 12 . The second row represents the current I_Q1 flowing through the high-side switch of the power converter. The third row represents the current I_Q2 flowing through the low-side switch of the power converter. The fourth row represents the current IL flowing through the inductor of the power converter. The fifth row represents the signal V1 shown inFIG. 12 . The sixth row represents the signal V2 shown inFIG. 12 . The seventh row represents the signal V3 shown inFIG. 12 . The eighth row represents the output voltage VER of the error amplifier and the voltage VFB on the feedback node. The solid line is VER, and the dashed line is VFB. The ninth row represents the gate drive signal VGS1 of the high-side switch of the power converter. The tenth row represents the gate drive signal VGS2 of the low-side switch of the power converter. - In operation, during the time interval (from t1 to t2) in which the high-
side switch 702 is on, the inductor current IL is charged from zero, and the output ripple voltage increases. In response to the increased output ripple voltage, the voltage on the feedback node FB increases too. Since the voltage on the feedback node FB is fed into the inverting input of the error amplifier (shown inFIG. 6 ), the output voltage of the voltage error amplifier decreases. Once the constant on-time interval expires, the constant on-time generator 715 pulls the control logic signal V1 low (from a logic high state to a logic low state at t2). In response to this short low pulse, the control logic andgate drive circuits 711 turn off the high-side switch 702 and turn on the low-side switch 703 at t2 as shown inFIG. 13 . - Once the low-
side switch 703 is turned on, the current zerocrossing detection comparator 712 is enabled to monitor the current (I_Q703) flowing through the low-side switch 703, and the logic signal V2 changes from a logic low state to a logic high state at t2. Once the current flowing through the low-side switch 703 reaches zero, the logic signal V2 changes from a logic high state to a logic low state at t3. This logic state change of V2 causes the control logic andgate drive circuits 711 to turn off the low-side switch 703 at t3, and keep the high-side switch 702 off as shown inFIG. 13 . - During the time interval from t3 to t4, both
switches output capacitor 705. - At t4, the voltage (VFB) at the inverting input of the
comparator 713 reaches the output voltage of the voltage error amplifier. Thecomparator 713 triggers accordingly. Thecomparator 713 generates a short low pulse at the control logic signal V3. The short low pulse at the control logic signal V3 enables the constant on-time generator 715. The control logic signal V1 changes from low to high. The logic state change of V1 causes the control logic andgate drive circuits 711 to turn on the high-side switch 702, and keep the low-side switch 703 off. The inductor current starts to charge up from zero. Once the constant on-time expires, the control logic signal V1 is pulled low and causes the control logic andgate drive circuits 711 to turn off thepower switch 702 and turn on thepower switch 703. The control logic signal V2 resets from a logic low state to a logic high state, and the zero currentcrossing detection comparator 712 is enabled. The PFM mode switching cycle repeats as shown inFIG. 13 . - It should be noted that the amount of energy delivered to the output can be controlled by adjusting the constant on-time interval.
- The transient response of the
power converter 700 is very similar to that of thepower converter 500, and hence is not repeated herein. -
FIG. 14 illustrates a flow chart of a control method for operating the power converter shown inFIG. 2 in accordance with various embodiments of the present disclosure. This flowchart shown inFIG. 14 is merely an example, which should not unduly limit the scope of the claims. One of ordinary skill in the art would recognize many variations, alternatives, and modifications. For example, various steps illustrated inFIG. 14 may be added, removed, replaced, rearranged and repeated. - At
step 1402, in a PWM mode of a power converter, a plurality of control switches is configured such that gate drive signals of the power converter are generated based on a comparison between an output of a PWM ramp generator and a predetermined reference. - At
step 1404, in a PFM mode of the power converter, the plurality of control switches is configured such that gate drive signals of the power converter are generated based on signals generated by an error amplifier and a current zero crossing detection comparator. - In some embodiments, a high-side switch and a low-side switch are connected in series between an input voltage bus and ground, wherein a common node of the high-side switch and the low-side switch is a switching node of the power converter.
- In some embodiments, an inductor is connected between the common node of the high-side switch and the low-side switch and an output of the power converter.
- In some embodiments, a PWM ramp generator is coupled between the switching node of the power converter and a first input of a comparator, and wherein the PWM ramp generator comprises a first resistor and a first capacitor connected in series between the switching node and the first input of the comparator, and a second resistor and a second capacitor connected in parallel between the first input of the comparator and a feedback node.
- In some embodiments, the comparator has an output coupled to control logic and gate drive circuits.
- In some embodiments, the error amplifier is coupled between a second input of the comparator and a reference node.
- In some embodiments, a current zero crossing detection comparator is coupled to the control logic and gate drive circuits.
- In some embodiments, a first control switch of the plurality of control switches is connected between the first input of the comparator and the feedback node. A second control switch of the plurality of control switches is connected between the second input of the comparator and the reference node. A third control switch of the plurality of control switches is coupled between the switching node and the first input of the comparator.
- The method further comprises in the PWM mode of the power converter, configuring the second switch and the third switch to be turned on, and configuring the first switch to be turned off.
- The method further comprises in the PFM mode of the power converter, configuring the second switch and the third switch to be turned off, and configuring the first switch to be turned on.
- The method further comprises in the PFM mode of the power converter, comparing a voltage on the feedback node with a sum of an output voltage of the error amplifier and a threshold voltage from a threshold generator to determine an on-time of the high-side switch of the power converter, comparing the voltage on the feedback node and the output voltage of the error amplifier to determine a turn-on instant of the high-side switch of the power converter, and determining, by the current zero crossing detection comparator, an on-time of the low-side switch of the power converter once a current flowing through the low-side switch of the power converter reaches zero.
- The method further comprises in the PFM mode of the power converter, comparing a current flowing through the high-side switch of the power converter with a predetermined peak current reference to determine an on-time of the high-side switch of the power converter, comparing a voltage on the feedback node with an output voltage of the error amplifier to determine a turn-on instant of the high-side switch of the power converter, and determining, by the current zero crossing detection comparator, an on-time of the low-side switch of the power converter once a current flowing through the low-side switch of the power converter reaches zero.
- The method further comprises in the PFM mode of the power converter, determining an on-time of the high-side switch of the power converter based on an output of a constant on-time generator, comparing a voltage on the feedback node with an output voltage of the error amplifier to determine a turn-on instant of the high-side switch of the power converter, and determining, by the current zero crossing detection comparator, an on-time of the low-side switch of the power converter once a current flowing through the low-side switch of the power converter reaches zero.
- Although embodiments of the present disclosure and its advantages have been described in detail, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the disclosure as defined by the appended claims.
- Moreover, the scope of the present application is not intended to be limited to the particular embodiments of the process, machine, manufacture, composition of matter, means, methods and steps described in the specification. As one of ordinary skill in the art will readily appreciate from the disclosure of the present disclosure, processes, machines, manufacture, compositions of matter, means, methods, or steps, presently existing or later to be developed, that perform substantially the same function or achieve substantially the same result as the corresponding embodiments described herein may be utilized according to the present disclosure. Accordingly, the appended claims are intended to include within their scope such processes, machines, manufacture, compositions of matter, means, methods, or steps.
Claims (20)
1. An apparatus comprising:
a PWM ramp generator coupled between a switching node of a power converter and a first input of a comparator, the PWM ramp generator comprising a first resistor and a first capacitor connected in series between the switching node and the first input of the comparator, and a second resistor and a second capacitor connected in parallel between the first input of the comparator and a feedback node; and
a PFM control circuit comprising an error amplifier and a current zero crossing detection comparator, wherein the error amplifier is coupled between a second input of the comparator and a reference node, and the PFM control circuit is configured to generate gate drive signal for the power converter when the power converter is configured to operate in a PFM mode.
2. The apparatus of claim 1 , wherein the power converter comprises:
a high-side switch and a low-side switch connected in series between an input voltage bus and ground, wherein a common node of the high-side switch and the low-side switch is the switching node of the power converter; and
an inductor connected between the common node of the high-side switch and the low-side switch and an output of the power converter.
3. The apparatus of claim 1 , further comprising:
a first control switch connected between the first input of the comparator and the feedback node;
a second control switch connected between the second input of the comparator and the reference node; and
a third control switch coupled between the switching node and the first input of the comparator, wherein:
the second control switch and the third control switch are configured to be turned on, and the first control switch is configured to be turned off when the power converter is configured to operate in a PWM mode; and
the second control switch and the third control switch are configured to be turned off, and the first control switch is configured to be turned on when the power converter is configured to operate in the PFM mode.
4. The apparatus of claim 1 , further comprising:
a divider comprising a third resistor and a fourth resistor connected in series between an output of the power converter and ground; and
a third capacitor connected in parallel with the third resistor, wherein a common node of the third resistor and the fourth resistor is the feedback node.
5. The apparatus of claim 1 , further comprising:
a threshold voltage generator coupled between the second input of the comparator and an output of the error amplifier, wherein:
the error amplifier is a transconductance operation amplifier;
a fourth capacitor and a fifth resistor are connected in parallel between the output of the error amplifier and ground, and wherein the fourth capacitor and the fifth resistor form a pole;
a non-inverting input of the error amplifier is connected to a predetermined reference;
an inverting input of the error amplifier is connected to the feedback node, and wherein:
a comparison of a voltage on the feedback node, and a sum of an output voltage of the error amplifier and a threshold voltage from the threshold voltage generator is used to determine an on-time of a high-side switch of the power converter; and
a comparison of the voltage on the feedback node and the output voltage of the error amplifier is used to determine a turn-on instant of the high-side switch of the power converter; and
the current zero crossing detection comparator is configured to determine an on-time of a low-side switch of the power converter once a current flowing through the low-side switch of the power converter reaches zero.
6. The apparatus of claim 1 , further comprising:
a peak current detection comparator, wherein:
the error amplifier is a transconductance operation amplifier;
a fourth capacitor and a fifth resistor are connected in parallel between an output of the error amplifier and ground, and wherein the fourth capacitor and the fifth resistor form a pole;
a non-inverting input of the error amplifier is connected to a predetermined reference;
an inverting input of the error amplifier is connected to the feedback node, and wherein:
a comparison of a current flowing through a high-side switch of the power converter and a predetermined peak current reference is used to determine an on-time of the high-side switch of the power converter; and
a comparison of a voltage on the feedback node and an output voltage of the error amplifier is used to determine a turn-on instant of the high-side switch of the power converter; and
the current zero crossing detection comparator is configured to determine an on-time of a low-side switch of the power converter once a current flowing through the low-side switch of the power converter reaches zero.
7. The apparatus of claim 1 , further comprising:
a constant on-time generator, wherein:
the error amplifier is a transconductance operation amplifier;
a fourth capacitor and a fifth resistor are connected in parallel between an output of the error amplifier and ground, and wherein the fourth capacitor and the fifth resistor form a pole;
a non-inverting input of the error amplifier is connected to a predetermined reference;
an inverting input of the error amplifier is connected to the feedback node, and wherein:
an output of the constant on-time generator is used to determine an on-time of a high-side switch of the power converter; and
a comparison of a voltage on the feedback node and an output voltage of the error amplifier is used to determine a turn-on instant of the high-side switch of the power converter; and
the current zero crossing detection comparator is configured to determine an on-time of a low-side switch of the power converter once a current flowing through the low-side switch of the power converter reaches zero.
8. The apparatus of claim 7 , further comprising:
a resistor-capacitor filter connected to the switching node, wherein the resistor-capacitor filter is configured such that an output voltage of the resistor-capacitor filter is used to determine an output voltage of the power converter fed into the constant on-time generator when the power converter is configured to operate in the PFM mode.
9. The apparatus of claim 1 , wherein:
the comparator is a hysteresis comparator;
the first input of the comparator is an inverting input; and
the second input of the comparator is a non-inverting input.
10. The apparatus of claim 1 , wherein:
a resistance value of the first resistor is at least ten times greater than a resistance value of the second resistor;
the second resistor is configured to provide a leakage path for the first input of the comparator; and
the first capacitor is configured such that a majority of a DC voltage difference between an output of the power converter and the feedback node is across the first capacitor.
11. A method comprising:
in a PWM mode of a power converter, configuring a plurality of control switches such that gate drive signals of the power converter are generated based on a comparison between an output of a PWM ramp generator and a predetermined reference; and
in a PFM mode of the power converter, configuring the plurality of control switches such that gate drive signals of the power converter are generated based on signals generated by an error amplifier and a current zero crossing detection comparator.
12. The method of claim 11 , wherein:
a high-side switch and a low-side switch are connected in series between an input voltage bus and ground, wherein a common node of the high-side switch and the low-side switch is a switching node of the power converter;
an inductor is connected between the common node of the high-side switch and the low-side switch and an output of the power converter;
a PWM ramp generator is coupled between the switching node of the power converter and a first input of a comparator, and wherein the PWM ramp generator comprises a first resistor and a first capacitor connected in series between the switching node and the first input of the comparator, and a second resistor and a second capacitor connected in parallel between the first input of the comparator and a feedback node;
the comparator has an output coupled to control logic and gate drive circuits;
the error amplifier is coupled between a second input of the comparator and a reference node;
a current zero crossing detection comparator is coupled to the control logic and gate drive circuits;
a first control switch of the plurality of control switches is connected between the first input of the comparator and the feedback node;
a second control switch of the plurality of control switches is connected between the second input of the comparator and the reference node; and
a third control switch of the plurality of control switches is coupled between the switching node and the first input of the comparator.
13. The method of claim 12 , further comprising:
in the PWM mode of the power converter, configuring the second control switch and the third control switch to be turned on, and configuring the first control switch to be turned off.
14. The method of claim 12 , further comprising:
in the PFM mode of the power converter, configuring the second control switch and the third control switch to be turned off, and configuring the first control switch to be turned on.
15. The method of claim 12 , further comprising:
in the PFM mode of the power converter, comparing a voltage on the feedback node with a sum of an output voltage of the error amplifier and a threshold voltage from a threshold generator to determine an on-time of the high-side switch of the power converter;
comparing the voltage on the feedback node and the output voltage of the error amplifier to determine a turn-on instant of the high-side switch of the power converter; and
determining, by the current zero crossing detection comparator, an on-time of the low-side switch of the power converter once a current flowing through the low-side switch of the power converter reaches zero.
16. The method of claim 12 , further comprising:
in the PFM mode of the power converter, comparing a current flowing through the high-side switch of the power converter with a predetermined peak current reference to determine an on-time of the high-side switch of the power converter;
comparing a voltage on the feedback node with an output voltage of the error amplifier to determine a turn-on instant of the high-side switch of the power converter; and
determining, by the current zero crossing detection comparator, an on-time of the low-side switch of the power converter once a current flowing through the low-side switch of the power converter reaches zero.
17. The method of claim 12 , further comprising:
in the PFM mode of the power converter, determining an on-time of the high-side switch of the power converter based on an output of a constant on-time generator;
comparing a voltage on the feedback node with an output voltage of the error amplifier to determine a turn-on instant of the high-side switch of the power converter; and
determining, by the current zero crossing detection comparator, an on-time of the low-side switch of the power converter once a current flowing through the low-side switch of the power converter reaches zero.
18. A system comprising:
a high-side switch and a low-side switch connected in series between an input voltage bus and ground, wherein a common node of the high-side switch and the low-side switch is a switching node;
an inductor connected between the common node of the high-side switch and the low-side switch and an output of the system;
a PWM ramp generator coupled between the switching node and a first input of a comparator, the PWM ramp generator comprising a first resistor and a first capacitor connected in series between the switching node and the first input of the comparator, and a second resistor and a second capacitor connected in parallel between the first input of the comparator and a feedback node; and
a PFM control circuit comprising an error amplifier and a current zero crossing detection comparator, wherein the error amplifier is coupled between a second input of the comparator and a reference node, and the PFM control circuit is configured to generate gate drive signal for the system when the system is configured to operate in a PFM mode.
19. The system of claim 18 , further comprising:
a first control switch connected between the first input of the comparator and the feedback node;
a second control switch connected between the second input of the comparator and the reference node; and
a third control switch coupled between the switching node and the first input of the comparator, wherein:
the second control switch and the third control switch are configured to be turned on, and the first control switch is configured to be turned off when the system is configured to operate in a PWM mode; and
the second control switch and the third control switch are configured to be turned off, and the first control switch is configured to be turned on when the system is configured to operate in the PFM mode.
20. The system of claim 18 , further comprising:
a divider comprising a third resistor and a fourth resistor connected in series between an output of the system and ground;
a third capacitor connected in parallel with the third resistor, wherein a common node of the third resistor and the fourth resistor is the feedback node; and
a resistor-capacitor filter connected to the switching node, wherein the resistor-capacitor filter is configured such that an output voltage of the resistor-capacitor filter is used to determine an output voltage of the system when the system is configured to operate in the PFM mode.
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US18/056,758 US12132401B2 (en) | 2022-11-18 | Buck converter and control method | |
CN202211652452.9A CN116613967A (en) | 2022-02-16 | 2022-12-22 | Buck converter and control method |
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US202263268112P | 2022-02-16 | 2022-02-16 | |
US18/056,758 US12132401B2 (en) | 2022-11-18 | Buck converter and control method |
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US20230299674A1 true US20230299674A1 (en) | 2023-09-21 |
US12132401B2 US12132401B2 (en) | 2024-10-29 |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20230396141A1 (en) * | 2022-06-02 | 2023-12-07 | Psemi Corporation | Circuits and methods for generating a continuous current sense signal |
US20240128869A1 (en) * | 2022-10-07 | 2024-04-18 | Infineon Technologies Austria Ag | Current mode controller and corresponding method of operation |
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US20230396141A1 (en) * | 2022-06-02 | 2023-12-07 | Psemi Corporation | Circuits and methods for generating a continuous current sense signal |
US12040692B2 (en) * | 2022-06-02 | 2024-07-16 | Murata Manufacturing Co., Ltd. | Circuits and methods for generating a continuous current sense signal |
US20240128869A1 (en) * | 2022-10-07 | 2024-04-18 | Infineon Technologies Austria Ag | Current mode controller and corresponding method of operation |
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